Method for identifying matched groups

ABSTRACT

Methods, code, and apparatus are used to ensure that groups of experimental subjects selected for inclusion in a study are matched. Individuals are genotyped and the genotype data is used to determine the extent of mismatch between study groups. If groups show evidence of poor matching, then the genotype data is used to better match the study groups.

BACKGROUND OF THE INVENTION

[0001] A case control association study may be used to identify genetic markers that are correlated with a phenotypic trait of interest, such as a predisposition to a disease, condition, illness, response to a drug, or other physical characteristic. The most useful and interesting associations are those that are functionally linked to the trait of interest. If case and control groups are not carefully matched to have similar genetic compositions, then studies may find spurious associations that have no causal relationship with the trait of interest.

[0002] Association studies have frequently been criticized for their inability to distinguish causal associations from spurious ones due to incomplete matching of cases and controls. Accordingly, further inquiry and analysis are always needed after completing an association study to understand the biological bases of any putative associations, and to determine which are likely to be functionally relevant. Following up on spurious associations can be difficult and expensive.

[0003] To reduce the likelihood of spurious associations, some studies have employed homogenous groups of individuals having the same ancestry (ethnicity), in some cases an ethnicity with relatively little genetic variation such as groups from Northern Europe and Iceland. The homogeneity of such groups may reduce the incidence of “false positives,” i.e., spurious associations between genetic markers and phenotypes that are in fact due to systematically unequal incidence of genetic markers in case and control groups. However, there are various disadvantages to using homogeneous groups in an association study. For instance, in some homogeneous populations, it may be difficult to find enough individuals with the phenotypic trait of interest, such as a particular disease, or it may be difficult to recruit enough individuals willing to participate in a given study. Additionally, the set of predisposing genetic factors in a restricted population may be less likely to be generalizable to or replicable in other populations. Hence, the usefulness of data derived from these studies may be limited.

[0004] Accordingly, nonhomogeneous groups (e.g., groups having a mixture of genetic or ancestral backgrounds) are frequently used in association studies. This mixture can occur as a result of combining individuals of geographically or genetically isolated populations in a study group, and/or having individuals of mixed ancestry in such a group. As indicated, study designs having groups of mixed backgrounds can present difficulties when trying to identify causal associations if the incidence of the phenotype of interest is correlated with genetic loci that are not causally-related to the phenotype of interest but whose correlation is simply due to the unmatched nature of the populations being compared. Association studies have traditionally been designed with only limited attention to matching, often limited to the level of “ethnicity matching” by ascertaining self-reported ethnicities from the participants. This self-categorization may be unreliable and may not accurately reflect the detailed population structure of the groups being studied.

SUMMARY OF THE INVENTION

[0005] The techniques of the present invention address a need in the art by providing methods that identify whether groups in an association study are “matched.” This is accomplished by comparing distributions of alleles in the groups at various genetic markers. In some preferred embodiments, the methods of the invention are utilized before the association study is conducted. If the distributions vary by more than a statistically acceptable level, one or both groups may be adjusted to bring the distributions into closer agreement.

[0006] Thus, one aspect of the invention pertains to methods for identifying matched groups prior to performing a study. Such methods may be characterized by the following sequence of operations: (a) prior to performing a study, identifying members of a control group and members of a case group; (b) for each of a number of selected genetic markers, genotyping a plurality of members in the control group and a plurality of members in the case group; and (c) determining if the groups are matched based on the genotypes of said case group and said control group. In (b) the genotyping identifies a set of alleles corresponding to the genetic markers for each member of the pluralities. Further, the genetic markers are selected to identify differences in population structure between members.

[0007] The invention may employ various methods and reagents for efficiently genotyping a plurality of individual samples for a plurality of biallelic genetic markers that have been selected for identification of population structure differences among members of a study population that are unrelated to a phenotypic trait of interest. One such method may be characterized by the following sequence: (a) PCR amplification of DNA samples in an optimized multiplex format; (b) fragmentation and fluorescent labelling of the amplified DNA products; (c) hybridization of the labelled products to oligonucleotide arrays designed for genotyping of diploid genetic material; and (d) analysis of fluorescence intensity data to determine individual marker genotypes.

[0008] Another aspect of this invention pertains to methods for analysis of genotype data from a plurality of markers, to determine whether an association study is at risk for finding spurious associations due to population structure. If corrective action is required, the same methods can be used to ascertain whether the corrections to the composition of the case and control populations are sufficient to reduce the incidence of spurious associations to a nominal level. The methods are of particular application to association studies that employ pooled genotyping, because detection of and correction for population structure must be done prior to pooling.

[0009] Another aspect of this invention pertains to methods for selecting matched case and control groups in an association study, using population structure information inferred from genotype data for a plurality of genetic markers. One variation involves selection of members of case and control groups to have the same proportions of individuals from a series of groups having relatively similar genetic backgrounds. Another variant involves selection of cases and controls to have the same over-all proportional representation of their ancestral populations, without requiring similar distributions for the individuals composing the groups. A third variant involves adjusting a measured quantitative phenotype to account for population structure differences, and then defining case and control groups based on the adjusted phenotype.

[0010] Yet another aspect of the invention pertains to computer program products including machine-readable media on which are provided program instructions for implementing the methods described above, in whole or in part. Frequently, the program instructions are provided as code for performing certain method operations. In addition, the invention pertains to various combinations and arrangements of data generated and/or used as described herein.

[0011] These and other features and advantages of the present invention will be described in more detail below with reference to the associated figures.

BRIEF DESCRIPTION OF THE DRAWINGS

[0012] The techniques of the present invention may be understood by reference to the following description taken in conjunction with the accompanying drawing figures, in which like parts may be referred to by like numerals.

[0013]FIG. 1 is a process flow diagram illustrating an exemplary process for identifying and creating groups with matched compositions.

[0014]FIG. 2 is a process flow diagram illustrating an exemplary process for genotyping an individual.

[0015]FIG. 3A is a diagrammatic representation of an amplicon.

[0016]FIG. 3B is a diagrammatic representation of a single nucleotide polymorphism.

[0017]FIG. 4 is an exemplary table showing allele counts and association test statistics in case and control groups.

[0018]FIG. 5 shows exemplary quantile plots for chi squared statistics from unmatched versus matched case and control groups.

[0019]FIG. 6 is an exemplary table showing the distribution of expected and observed p-values for tests of association of individual loci with a phenotype.

[0020]FIG. 7A is an exemplary stratification table for case and control groups.

[0021]FIG. 7B is an adjusted version of the exemplary stratification table for case and control groups.

[0022]FIG. 8 is an exemplary graph showing mean curves for case and control groups.

[0023]FIGS. 9A and 9B illustrate a computer system suitable for implementing embodiments of the present invention.

DETAILED DESCRIPTION OF INVENTION

[0024] Association studies may be used to identify genetic markers that are correlated with a phenotypic trait, such as a predisposition to a disease, a chronic condition, illness, or other physical characteristic. A major challenge in carrying out these kinds of studies is to determine whether observed correlations between markers and traits have a causal basis. In an ideal association study, the only genetic differences between the case and control groups would be the loci that are causally-related to the phenotypic trait of interest, i.e., their population structures would be nearly identical. Population structure refers to the heterogeneity and genetic composition of individuals within a population. Although this strategy may be applicable to highly inbred organisms, such as laboratory mice, this is not possible in human populations due to the vast amounts of variation between individuals, much of it relating to ethnicity or ancestral heritage, and not to the trait of interest. Some association studies attempt to control for this variation, but “ethnicity matching” by ascertaining self-reported ethnicities from the participants is unreliable and may not accurately reflect the population structure of the groups being studied. Many individuals may not be able to provide an accurate account of their ethnic heritage, especially in North and South America, where immigration and ethnic mixing have been extensive and extend over significant numbers of generations. As indicated, other studies attempt to get around this issue by using homogeneous populations in association studies, but this strategy limits the study design and the usefulness of the data produced in various undesirable ways. For example, the size of the case and control populations may be limited and the set of predisposing genetic factors in a restricted population may be less likely to be generalizable to or replicable in other populations.

[0025] Thus, to find the set of predisposing factors that are most applicable to the greatest number of individuals outside of the study populations, a nonhomologous population is desired. However, with that kind of population comes an increased risk of identifying spurious associations, or “false positives”. Hence, the population structure of case and control groups must be balanced, or “matched” in order to increase the likelihood that correlations identified in a study stem from a causal relationship between a genetic locus and a phenotypic trait of interest. If the case and control groups of an association study are genetically unbalanced in some regard, aside from the phenotypic trait of interest, then the imbalance may be incorrectly associated with the trait of interest, generating a false positive. Therefore, what is needed is a way to measure and control for the population structure of nonhomologous populations.

[0026] As an example, consider a case group biased toward European ancestry in a study on prostate cancer. A researcher considering alleles that are more common in the case group than the control group may falsely conclude that some such alleles are functionally linked with the phenotype of interest, prostate cancer, when in fact they are correlated with European ethnicity. If the case and control groups are genetically unbalanced in any way other than in the phenotype of interest, one cannot safely determine which markers are causally related to the phenotypic trait of interest.

[0027] To further illustrate this point, consider an association study intended to identify markers related to hypertension, in which two groups of individuals are compared: one group having hypertension (the case group) and the other without hypertension (the control group). The members of the groups have been surveyed in an attempt to balance phenotypic traits other than hypertension, and are all of Western European ancestry. Further, the researchers chose certain genetic markers for comparison between the two groups. These may be selected to fall in candidate regions suspected of having a role in the phenotype of interest, or may be selected without regard to a specific prior hypothesis regarding their biological function. Regardless, the allelic differences between individuals in the groups are identified at the various markers chosen for study. A particular allele or group of alleles may appear to correlate with the individuals having hypertension. However, upon further inquiry, it is discovered that the group having hypertension includes a higher proportion of individuals with Italian ancestry. This may have occurred because of a defect in how the case and control groups were ascertained or because individuals with Italian ancestry tend to have a high incidence of hypertension, possibly as a result of environmental influences.

[0028] Either way, this ethnic mismatch between the two groups in the association study may lead researchers to incorrectly conclude that an allele associated with Italian ancestry is causally associated with hypertension. Researchers will not be able to distinguish which of the identified markers might generally be associated with Italian ancestry and which of the markers might generally be associated with hypertension, because these outcomes are confounded in this study population. Accordingly, further inquiry and analysis is needed to determine which of the genetic markers relate to hypertension.

[0029] Instead, had the two groups been matched before the association study was conducted, the confounding population structures of the case and control groups could have been corrected, saving much time, effort, and expense. If the two groups had approximately equal degrees of Italian ancestry, then markers associated with Italian ancestry would be unlikely to show up as differences in allele frequencies between the two groups. One way of determining the ancestral make-up of a group of individuals before conducting an association study is to ask the individuals in a survey. However, as previously described this method is unreliable for measuring population structure in a study group. Accordingly, more accurate methods of identifying matched groups before conducting an association study are desirable.

[0030] The techniques of the present invention address the above issues and needs by measuring the population structure of groups to identify matched groups before conducting an association study. More particularly, according to various embodiments, two groups of individuals are chosen and genotyped for a relatively large group of genetic markers (e.g., 100 or more). Using the results of this genotyping, differences in population structure between the groups are identified based on statistically significant differences in allele frequencies between the two groups. Using the information contained in these differences, the groups are adjusted until they are matched. When the groups are matched, they are ready for use in an association study.

[0031] Turning now to FIG. 1, an exemplary process is depicted for comparing the population structures of two or more groups and for balancing such groups to produce modified groups having more matched compositions. At 100, individuals selected to participate in an association study are identified as initial members of case and control groups, respectively. Members of the case group are chosen because they exhibit the phenotype of interest, such as a predisposition to a disease, condition, illness, a particular response to a drug, or other physical characteristic. Members of the control group are chosen because they lack the phenotype of interest. In other situations, case and control groups may be defined as ranges of values of a quantitative trait. For example, a “low cholesterol” control group may be comprised of individuals whose total blood cholesterol count is 200 mg/dL or less, while the “high cholesterol” case group may be comprised of individuals whose total blood cholesterol count is greater than 200 mg/dL.

[0032] Next, at 102, individuals in the case and control groups are genotyped using a set of genetic markers chosen to indicate differences in population structure. Various types of genetic markers can be used for this purpose. Examples include multi-allelic single nucleotide polymorphisms (“SNPs”), microsatellites, and the like. The markers preferably are sufficiently far apart that they do not exhibit significant linkage disequilibrium. Preferably, the markers will be substantially uniformly distributed across the genome. Generally, the method should employ 100 or more, and even more preferably about 300 or more. In one implementation of this invention, 312 SNPs were used to genotype each of the individuals, as described in more detail below with regard to FIG. 2.

[0033] Each genetic marker is found at a particular region (or “locus”) of interest in a genomic sequence. For an individual locus on a single strand of DNA, only one of a plurality of alleles is present, and is characterized by the nucleotide sequence at that locus. For example, bi-allelic SNPs have only two alleles; so, at a given bi-allelic SNP locus on a single strand of DNA, only one of two alleles (i.e., adenine (“A”), thymine (“T”), guanine (“G”), or cytosine (“C”)) will be present. In certain preferred embodiments, bialleleic SNPs are used, and in more preferred embodiments these SNPs are common SNPs (SNPs that have a minor allele frequency of at least 10%). Further, although the examples provided herein will primarily discuss detection of SNPs in DNA, SNPs may also be detected in DNA derivatives, such as RNA or cDNA, and the like, as will be clear to those of skill it the art.

[0034] For the sake of convenience in this description of the techniques of the present invention, the two alleles of a bi-allelic marker (e.g., a bi-allelic SNP) will be arbitrarily referred to as X and Y, regardless of which of the actual alleles characterize that particular genetic marker. For example, a SNP marker may have A and G as alleles. For convenience, these will be referenced as binary values X and Y. The same would be true for a different SNP marker, where the two alleles are C and T, A and T, G and C, G and T, or A and C.

[0035] Understand that SNPs are not the only types of marker that can be used. Any stable genetic feature having alleles that are differentially distributed across populations can be used. One example already mentioned is a microsatellite, which is a sequence of highly variable length that contains di- or tri-nucleotide repeats. Microsatellites can repeat for any number of times. For example, a microsatellite having the following sequence, ATGATGATG, is three bases long and repeats three times. Even when a given microsatellite is present on multiple chromosomes in an individual, it may vary in the number of repeats present on each chromosome. For example, ATG microsatellite may repeat 3 times in some chromosomes, 5 times in others, and 8 times in still others. Hence the number of repeats in a particular microsatellite can serve as a genetic marker in accordance with this invention. Other markers that could be used include VNTRs (variable number of tandem repeats), STRs (short tandem repeats), RFLPs (restriction fragment length polymorphisms), insertions, deletions and the like.

[0036] Each individual is genotyped to provide two allele values (one for each chromosome) for each of the genetic markers. Genotyping can be conducted by any reliable, efficient method for distinguishing the possible alleles. Note that individuals have two copies of every chromosome. So they have two copies of each marker, which means that they have two allele values for each marker. As a consequence, the genotyping procedure will identify two allele values for each individual. As described in more detail below with regard to FIG. 2, genotyping can be conducted by applying a DNA sample to a DNA array to determine which alleles the individual has for each of the genetic markers. Such arrays are commercially available from, e.g., Affymetrix, Inc., (Santa Clara, Calif.). Of course, other methods are also suitable; for example, direct sequencing of the regions encoding each marker.

[0037] After collecting the individual genotypes, the distributions of alleles in cases and controls can be compared with the distributions expected if the same numbers of cases and controls were randomly selected from one homogeneous population. As illustrated at blocks 104 and 106 of FIG. 1, a typical procedure characterizes each marker by a difference in allele frequency between the case and control groups. It compares this information with expected values to draw a conclusion about how well the groups match. Several such methods are available and should be familiar to those skilled in the art. These methods rely on the expectation that few or none of the markers selected for the stratification analysis are likely to have any functional association with the phenotype used to define cases and controls, so any evidence for associations in these few markers is evidence that cases and controls are inadequately matched.

[0038] One such method is to perform, for each marker, a chi squared test of independence of the individual allele counts in cases and controls. Each such test produces a score statistic, and the set of score statistics for all markers should conform to a chi squared distribution with one degree of freedom. A “Q-Q” plot of the ordered scores against corresponding chi squared quantiles should have a slope of 1 in the situation where cases and controls are well matched, and gives a simple visual interpretation of the quality of fit between the expected and observed distributions. Q-Q plots are known to those of skill in the art. See Wilk, M. B. and Gnanadesikan, R. (1968) “Probability plotting methods for the analysis of data”, Biometrika 55:1-17, which is incorporated herein by reference in its entirety for all purposes.

[0039] A closely related method involves calculating, for each marker, a “p-value” representing the probability of observing as extreme a chi squared statistic as the observed one by chance, assuming that the marker is not associated with the phenotype. It is expected that, assuming cases and controls are well matched, 10% of the markers selected for the stratification analysis should exhibit p-values of 0.1 or lower; 1% of the markers should exhibit p-values of 0.01 or lower; and so on. An excess of markers that exhibit small p-values hence indicates that the case and control groups are not matched. The use of p-values and chi squared statistics are known to one of skill in the art and are described in greater detail in Bevington, P. R. and Robinson, D. K., Data Reduction and Error Analysis for the Physical Sciences, Second Edition, McGraw-Hill, Inc., 1992.

[0040] A third related method exploits a property that the sum of the chi squared statistics for N individual markers should follow a chi squared distribution with N degrees of freedom. This method allows determination of an overall (“global”) p-value for the complete set of markers. The global p-value gives the probability of seeing a similarly extreme set of chi squared statistics assuming that the groups are matched. Thus, the groups are determined to be matched if the p-value exceeds an acceptable threshold. An acceptable threshold is typically dependent on the desired level of population structure similarities between groups in a particular study. For example, a higher threshold would require a higher degree of similarity between the population structures of the groups as compared to a lower threshold. This method is of limited utility, however, because given a sufficiently large number of markers, fairly small differences between cases and controls could give impressively small p-values even though these differences would be unlikely to result in large numbers of spurious associations. Further description of the global p-value test is described in Prichard, J. K. and Rosenberg, N. A. (1999) “Use of unlinked genetic markers to detect population stratification in association studies”, Am. J. Hum. Genet. 65:220-228, which is incorporated herein by reference in its entirety for all purposes.

[0041] Using a technique such as one of those identified above, the process determines whether a difference between observed and expected differences in measured allele frequencies is “acceptable.” See decision 108. If it is determined that the allelic differences between cases and controls are inconsistent with the hypothesis of a homogeneous population, and the differences are sufficiently large that the study is anticipated to produce unacceptable numbers of spurious associations, then at 114, the case and control groups can be adjusted to provide better matching. The adjusted groups can then be tested in silico using the already collected genotype data at 106, to see if the adjustment is sufficient to reduce the expected numbers of spurious associations. This process continues until the population structures of the case and control groups are matched to the degree required at 108, at which point the process continues to its conclusion at block 112, typically via performance of an association study as indicated at block 110. Although FIG. 1 is shown with a specific sequence, it should be recognized that portions of the sequence can be combined or rearranged without departing from the present invention. For instance, 104 and 106 can be combined in some embodiments. Furthermore, 114 can be followed by 104, or even 102 if new members are added to the groups, instead of 106 in some embodiments. And, as indicated, after the groups are matched, then these matched groups can be used in an association study at 110 to identify markers that correlate with a phenotypic trait of interest. Association studies may be performed by many methods known in the art. Specific descriptions of preferred embodiments are disclosed in U.S. patent application Ser. No. 10/106,097, filed Mar. 26, 2002, entitled “Methods for Genomic Analysis”, which is incorporated herein in its entirety for all purposes.

[0042] With reference now to FIG. 2, an exemplary process for genotyping an individual is shown. This process may correspond to operation 102 of FIG. 1. As a prelude to the FIG. 2 genotyping process, the researchers must identify a group of genetic markers to be used as described above. These are the markers used in the genotyping methodology of FIG. 2. Fundamentally, the markers should come from unlinked genetic loci. Otherwise some of the markers would provide no additional information beyond that provided by a linked counterpart. And there should be a sufficient number of them to provide a trustworthy representation of population structure. Preferably, as indicated above, there are at least about 20 such genetic markers, more preferably between about 100-1000, more preferably between about 200-500, and even more preferably, at least about 300.

[0043] One set of criteria for choosing markers that has proven useful includes the following. First, the markers should be polymorphic across widely diverse populations, for example, those comprised of individuals from different ethnicities, geographic locations and ancestral backgrounds, such as individuals from African, Asian, European, Native South American, and Native North American ancestries. In other words, various alleles for a given marker should be present in a wide range of different populations. So, in this approach, the different alleles of a marker should be polymorphic across a group of individuals having widely varying ethnic backgrounds. For example, for a biallelic SNP, both alleles should be present in most of the world's populations, but the allele frequencies may vary widely. In fact, it is desirable to choose markers whose allele frequency is variable across different populations. Second, the markers should be separated from one another by a sufficiently large distance, so that they are unlikely to be correlated, or “linked”, with each other. The haplotype structure of the human genome indicates that strong correlations exist on scales of 10 to 100 kilobases. A spacing of at least about 5 megabases, preferably at least about 8 megabases, and more preferably at least about 10 megabases is sufficient to minimize these correlations.

[0044] Third, the markers are preferably chosen to perform well in the physical technique employed to identify alleles (i.e., genotype). Genotyping techniques may utilize enzymatic, electrophoretic, chromatographic, or physical methods for discriminating allelic variants. For example, allele-specific PCR, allele-specific single-base primer extension, allele-specific ligation, allele-specific enzymatic cleavage, or nucleotide analogs (e.g., peptide nucleic acids and locked nucleic acids) may be used to discriminate between alternative alleles at a genetic locus. Detection methods for genotyping may involve, for example, fluorescence detection, fluorescence resonance energy transfer, fluorescence polarization, electrochemical detection, mass spectrometry, or atomic force microscopy. Genotyping may be carried out in solution or on a substrate, which includes but is not limited to oligonucleotide chips or bead arrays. So, if for example, the techniques employs DNA microarrays, DNA samples containing the chosen markers should hybridize well with a probe array on a DNA probe array chip or DNA probe array wafer. If the technique employs PCR amplification of nucleic acids, the markers should amplify reliably. Other techniques that may be used to genotype the markers include, but are not limited to, “Taqman” kits (Applied Biosystems (Foster City, Calif.)), “Invader” genotyping products (Third Wave Technologies (Madison, Wis.)), “the MassARRAY system” (Sequenom (San Diego, Calif.)), and the like.

[0045] In one example, SNPs were selected as genetic markers using the following procedure. First a full set of approximately 1.7 million known human SNPs, identified by Perlegen Sciences, Inc. of Mountain View, Calif., were considered. From this set, SNPs near “contig boundaries” or known repetitive elements (within approximately 150 base pairs) were eliminated from consideration. This was done for the purpose of increasing the probability of designing appropriate PCR primers for the SNP. Contig boundaries resulted from the process employed to sequence the human genome. They represent boundaries between separate sequences mapped in the process and they may be unreliable. Repeat units can be identified by publicly available programs such as RepeatMasker. Obviously, reliable amplification with PCR is difficult in cases where the amplicon is located near repeat units.

[0046] To ensure that the markers are well represented across diverse populations, a group of individuals of diverse ancestry were genotyped. Twenty chromosomes were considered from this globally diverse panel. The allele frequency of SNPs remaining after contig/repeat filtering was considered. The process eliminated SNPs having fewer than 8 calls (out of 20) for either allele. So preferably biallelic genetic markers have allele frequencies of between about 40 and 60 percent across a widely varied population.

[0047] Optionally, SNPs near a haplotype block boundary may be eliminated from consideration. For example, in certain embodiments, any SNP not more than 2 SNPs away from a haplotype block boundary may be eliminated. This may reduce the odds that a selected SNP will behave differently from other SNPs in its vicinity and increase the probability that a selected SNP will exhibit behavior that is consistent with the SNPs in its vicinity.

[0048] Using the surviving SNPs, the inventors calculated a score based on three criteria: the estimated allele frequency, the rate at which they could reliably identify the allele of a particular SNP on SNP discovery probe arrays (“strict call rate”), and the average conformance of long range PCR amplicons on the arrays. More specifically, the strict call rate is the fraction of SNP discovery probe arrays for which the forward and reverse tilings of the SNP both yielded the same allele determination with a very high confidence level. Conformance is a measure of the fraction of base calls that match a reference sequence. Particular embodiments of forward and reverse tilings for SNPs and methods for calculating conformance are detailed in patent applications U.S.S.N. [unassigned], attorney docket number 1026U1, filed Apr. 3, 2003, entitled “Apparatus and Methods for Analyzing and Characterizing Nucleic Acid Sequences”, and U.S. Ser. No. 10/351,973, filed Jan. 27, 2003, entitled “Apparatus and Methods for Determining Individual Genotypes”, both of which are incorporated herein by reference for all purposes. For the allele frequencies, the score gave better ranks to SNPs that were closer to a frequency of 50 percent. The strict call rate was a test for good hybridization properties of the sequence containing the SNP itself. The conformance test was a measure of both PCR success and overall quality of hybridization across the region of the containing the SNP. The formula for the score was the following:

Score=0.25*[1−2*abs(freq-0.5)+2*calls/scans+avgconf]

[0049] The score varies from 0 to 1, with a value of 1 being perfect. Initially, the inventors discarded all SNPs with scores of less than 0.70.

[0050] For the remaining SNPs, for each chromosome, starting at a position of 1 Mbase, the inventors picked the highest scoring SNP within +/−1 Mbase of that position. From there, they added 9 Mbase, and again picked the best SNP within +/−1 Mbase, and so on. At the end of the process, 312 genetic markers were obtained.

[0051] In a specific example, the above selection criteria were used to choose 312 genetic markers. These were then used to identify differences in population structure between case and control groups. The 312 SNPs are included in Table 1. As shown, the SNPs are uniquely identified by a SNP number (sequentially chosen from 1-312), a chromosome number identifying the human chromosome on which the SNP is located, reference and alternate bases for the SNP (which identify the exact allelic values), and the 25mer sequence bracketing the SNP displayed in the conventional 5′ to 3′ orientation for nucleic acids (with the SNP being at position 13). TABLE 1 REF_(—) ALT_ SNP CHROMOSOME BASE BASE 25MER 1 1 g c TACCATCATTTTNGAATTGTTCAGA 2 1 c t GGCCTAGAGTTANGGCATTTCACTT 3 1 c t GAGAGTTCAATGNGTAAAGATGCCC 4 1 t c TAATTGGGGTTTNGTAACTAGCTAC 5 1 a g CAATTGCTCATCNAGTCCATGAAAG 6 1 t c GGTACGCTTCAANGTTATATGCGGT 7 1 c t GAGATCTCAAACNTTAATTTTACTG 8 1 g c CAAGCTGAACCTNAATGTAGCTCCA 9 1 a t GTGTCCCACTATNTAAGAAATGTTT 10 1 g a TTAACCGTCTGTNCTCTCTACACGG 11 1 a t TATATCCAACCANCTCTTGGCTCTA 12 1 c a CGTAGGCCGTAANCTGATGCCATGA 13 1 g c CTTACTTTTCACNTTACTACTTGCA 14 1 g t TGAGTTATAGAGNTGAATCCATGTG 15 1 a c GAAAACCATTCTNAATTCCAGTTCC 16 1 g a CTAGGAGCTACANATAGTTCCAACC 17 1 c g CAATGGGAGATTNAGGCCTAGAGCA 18 1 a g AAGGTACATATTNGGATGAGATACT 19 1 t c TTGATAATTTGANTAAAGCTGACCT 20 1 c t ACTGGCTGCGCANGGACAAGTGTCA 21 1 c t TCATTCTTACCANTGGTGCTGAAAA 22 1 a g ATTTTTCAGCTTNATTTAACATTGT 23 1 t c TAATCTTTATTGNATTCTCATTGGC 24 1 c a GACAGTCTGCAANAAAATTTTCTGG 25 1 g a TTTACCAGGTCCNCCAAGACTATGA 26 1 g a TCACACAAAGGCNTAATCATGAAAA 27 1 g a GGAATTGTGCTANATACAAAAATGC 28 2 t c ACAGAAGTTAAGNTAAACGTTCTAA 29 2 g a AATAACTTCCGCNTAATGAGTACCC 30 2 c g CTGGCTTCAGAANTGATCTTTTCCT 31 2 a g GTATTTGTCTGANTCATAGAATTTA 32 2 a g CAAGTCACATCANGAAGTTGTGGGC 33 2 t a AACGGAACAATANTACATTCCTGGG 34 2 a c ATAAGCAGCCATNTTATTGAGAAGC 35 2 g a TAACAAACATAANATTTGCATTATA 36 2 g a TAAGGAGCTAATNGCCAATAATTAC 37 2 a g GGCAGGGAACCANTCTTTAGAAACT 38 2 g a TTCAAGGAACCCNTGTTGATAATAA 39 2 t c TTATACTACAGANGTTCATTATGCC 40 2 g a GCAGAATGCCCCNTCCGTAAATGTC 41 2 a g TTTGAATCAGAGNAGTGATTTTGAA 42 2 a c TCTGCGATCTGGNAATAGAGCTTTC 43 2 t c ATACCTCTCCAGNCACACATAATAA 44 2 g a AGTAATCACTTTNTGTCAAAATGTT 45 2 a g TCACTAGATGCANATTTCTTCATGT 46 2 g a AATTTCAGCAGANGGATTATGATGC 47 2 g a TAAAATTTTCCANGCTGGAGCAATT 48 2 a t AACAATCGAGGTNGGCTTTAAAGGA 49 2 c t GTTAGCACAGTTNATAGCAAGTCTT 50 2 a g ATTGCTTGGCACNTTCTCAGAGGTG 51 2 g a CGCTTCTTGCAGNGGAACTTCATGG 52 2 a g ACCATGTTGAGANTTGTGCCTAGCT 53 2 c g GCAGACCAGAGANTGTCAATTTAAG 54 2 g a ACATCTTAATGANGTGCTGACATTT 55 3 a g CTGATATAGGCCNTAGTGTCAGGAC 56 3 g a CATGAGATGGCCNTTTTCCAGGAGA 57 3 t c ATAACATCCTGCNGGTTACTGATCA 58 3 g a CCCTGGGAACACNCTACTGAGAGCC 59 3 c g TACTATGGGGAANAACTTGTCACTT 60 3 t c AACTTACTGGAANGGGAACTTTTCA 61 3 t c GATACCCTTATANGGCAGAACTTTA 62 3 t a CTGTTGGGAAACNCTTCAGTCACAC 63 3 g a GGGTACAATTAGNTCTTACTCATGC 64 3 c t CAATTTCGTACANTTGAAAGAGACA 65 3 c t GCCTTACAGAGCNGTGATTTTGGCT 66 3 a g AATCCTGACGGTNGGTTCTACAATT 67 3 t c TTTCAAGAGGTGNGAGGACAAGGCC 68 3 a g CATTCCTGGCTGNTCGTAGACAAGG 69 3 a g GAATCAGAAGGCNAAATGTTTGGGC 70 3 c g AACGTGGAACAANAGTGAAAAAATG 71 3 a g GTGTTTACTCCANAATACCAGCTTA 72 3 a g AAAGGGTCAGTCNTTGAAACATTGC 73 3 a g CCAGTGCCCGGCNAGTAACCAACGC 74 3 t c AAGTGTGCATAANGTAGAGACTCAT 75 3 g a TGACTTTAGAGCNTAGTATTTTAGC 76 3 c t TAGGTGGCAAATNGATACCCTGAGG 77 3 c a TGATTTTTGGATNGGAAAGGAGACT 78 3 g c GCGAGGACCTATNGGATGTGTAGGC 79 3 g a CATGGCGCTTTANCACAAGTATGGA 80 4 g c TCTGAAACCATCNCAGGAATGATGC 81 4 t c TTCTAGTCTCCTNCCCGGGCGGTCA 82 4 a c GCTGAGAATTTCNAGTGTGATCGGT 83 4 c t TGGTTTCTTGCANTGGGAGGGAGAC 84 4 c t TATGTAAAAGCANGTGTCATTATGA 85 4 t c TCACATTTTCTTNCAAAGGCAAGTA 86 4 t g TTACTGAACAAANTATCATCTCAGG 87 4 c t TGAATAATGCCTNTAGGGTCTGAAT 88 4 t c CACTTTACGGCTNTCACCATTCACA 89 4 a g CTTTGAAATCTTNTAGTTCTGCTGC 90 4 t c TTCCTCACTGTANTGCTTATTCTCT 91 4 t c GAGCCTGGCATANGAAACAATTTCC 92 4 g a GAACACAATAACNAAACAGATGATG 93 4 t c CTGGGTTGCTTCNTGTAAACCTGCA 94 4 g a CTAAAAGTAAATNTCGGTATCAGTG 95 4 g a TAGATAGCATGCNGCTTCAAGAAGA 96 4 c t CAGCGATGTTCANTGGCGGCTTATT 97 4 g a CACTAATCAAGTNCACTAGCCCTCC 98 4 g a CTTTTTACCACTNAACTCTGGAATG 99 4 a g TTCAAATCATCCNCAGACTTGTTCA 100 4 a g TGTTTTCTGGACNCATAGCTCATGT 101 4 t a CTGGGCAAATCANCCATTAACACTC 102 4 t a TTTTGGAGGACCNCAATCATGGTTC 103 5 c t ATTACCTCCTTANGCAAATGACCAC 104 5 g a GAATCGTGGGGCNTTTTGGCAGCCT 105 5 t c ACACTACAGTAANACCTCTAGCCCA 106 5 g t AAACATGATTATNCTCCTGCATTGA 107 5 c a GGAACTGGAAAGNAACTTCCATCAG 108 5 c t TGTCAGGCACTTNAGGGCATTGACC 109 5 g a GGAGCCATGAGANTTATTGCGGCCC 110 5 c t TGTGCTTTCTGANGCCTACCTCCAA 111 5 c t AAGTGGAGGGCGNTCATTCCATCCT 112 5 g a GAAATCATGTCCNCCCTTTTCCAGT 113 5 c t TACCTATTCGCCNTCCATGAAACAG 114 5 t c TGAGATTTCCTANGATGGAAGTGTG 115 5 t c CTGTTTCCTTTCNGGTTGGTTCGTT 116 5 t c CGCAGTACAAGGNTTCCCTAGTAGT 117 5 t c ACAGTATTTGGANGGCTGACTAAAA 118 5 g a CTAAAAGTGGACNAGAGCCTTAAAA 119 5 c g AAAGCCTCCACGNGACAACAGTTTC 120 5 a g GAGACCTCAAAGNTTCACAACATGA 121 5 t c TCACTGCATATANTAACATAAAAAC 122 5 a g TATTATTATCCCNTTGTAAATGTTT 123 5 a g ATATTGTCACTGNTGCCCTTGATTG 124 5 c t GCACCTAACCATNTGCTGACGTGGC 125 6 c t TTACAGGTTTCANTTTTTTATCGTC 126 6 t a AAAAGTTTAGGANCATAGTAAGGTT 127 6 t g AAACTCTATGCTNTGGCCTTTCATA 128 6 c t CATTATGAATTCNTTCGTCACTGAT 129 6 g t AAGGCAGAGCACNTTTCTGTGGTTC 130 6 c t TTTAGAAATAGCNGGTGATTACAGA 131 6 g c TACAGAACCTTANACAGACTACGTA 132 6 g c CAGAGCTTATTCNTTCTACCTTGTT 133 6 a g GCATGTCTCACANCATTACGAATGG 134 6 t c TGCATAGTAATCNTTCATTCAGCAC 135 6 c t TAGCTACAGTTANCGATTCCGCTTA 136 6 c t AGTATTTGTCAANTAATGCTGTTAA 137 6 g t AAGGCTTTCCTGNAAAAGTAGCTGT 138 6 a c TAGCAGCATTCANGGGACTCAGGTG 139 6 t c GCAATAGCTAATNGAGTTCCTGATT 140 6 t a TACTTTGATTAANGGCTGATGATAT 141 6 g c TTAAAATTTGTCNGTGCCAATTTAG 142 6 t g TACCTGTGTAAANAAATTGATAACA 143 6 g a GTCCAATTAGCANTAAGTGCCATGC 144 6 t g CTTTTGTTCATTNGATAATCGGGTG 145 6 a g GAATGTCTGCTCNGTTACAACGTGA 146 7 t c GCATGTATTGTCNATCCAAAAACTT 147 7 a g AATTCAGACCACNCTTAGGGAATCA 148 7 t c GTCCACAAAGGTNTGGAATATAAAA 149 7 g t TTGTGATATTCCNCCAAAGTAAACA 150 7 g t TCTGTACCTCATNTACTTGTAGTCT 151 7 t c ACTCAGGTGCATNCAGAGCCGAAGG 152 7 c t AGTCAATGCTTANTTAAGCTTATTC 153 7 g a ACATGGTAGCAGNAAATGAGAGCGT 154 7 t c GTTATAAAGCCTNTCCAGGTGCAGA 155 7 c t TCAAGTGCCTGCNACAAGTAAATAG 156 7 g a CATGTATAAGCCNAAAGCTAAAACG 157 7 c t CACTCGAGCATGNGGCATTATTTAA 158 7 c t ATCAGTCATTTCNGGCTCTTTATGT 159 7 t c AGCCAAACCATANCTAGTTTCCAAA 160 7 c t ATGTGATACTTANGAATTCCACCAG 161 7 g a GTACCTCTAGACNTCCATACAGCTT 162 7 g a ACAGCTGAGTGANAACAAAATGGAC 163 7 g a TACAGTACAGACNTTGATGAGACCA 164 8 g c AGTCTTATCTTTNGGACAAATGGAA 165 8 g a TCCAAGCCTCCCNGAATGAAACTTT 166 8 g c CCACTTCTAATANCTTTCACAAGAC 167 8 t a CGTAAACTGAGCNGACCTGTACCCT 168 8 t c CTGTGTTAAACTNCCAGATGGCAGT 169 8 g c CAGCTGGAAACANGTCTGGGCTCTT 170 8 g a GTTAACCAGCCTNAATGCAAAAAGT 171 8 c t AACAGCCAGAGTNCCTGTAAGAGCA 172 8 c t GGCATACATCTTNCTTAACCTACAT 173 8 c g GGTCCAAAAGTCNTGCTAGGTATCT 174 8 g a GGCAAGACCTCANAATAACTTAAAG 175 8 a t ATGCGTAGGTTANGGTCCTAGTTCA 176 8 c a GTGCTACTTTGANTGTGAAAATACA 177 8 t c CTCAGGAAAGAANTGCCACTTCGAA 178 8 c t ATTTGATGTGACNGATAGCTCCAGA 179 8 c t CAGAGCCAAAAANGTTGCTCTTCCA 180 8 t c ATGCTACTGATANGTAATCACAATG 181 8 g a ACCCTTTCTACTNTACTATCACAGC 182 9 g a CAGTGTTCTTTGNGGTTCCACTCTT 183 9 t c CTAGTGCTTTCANGATGCCCTTAGT 184 9 c t GTTACCCTTACANGTGGCTGTTTGC 185 9 t a TTCTAACTCTCANTTAAGTGAGGCA 186 9 a g CTCACATTACCCNACTTTGGGCCCT 187 9 t c GCCAATGTTTAGNGGAGATATTTCT 188 9 c t TGTTCAAGCCATNGATATTAGGTTG 189 9 t c GTGTGATGCTCTNTTTTGACCCACA 190 9 t c CTTTTCTAATACNGCAATATTTCAA 191 9 g a TGAAACTTAGGCNGAATAGTAAGTA 192 9 a g TATCATGGGACCNTCCTATAAGGTT 193 9 a g TGGAGAGAGGCCNTTTCCTAATCAG 194 10 c g CCTGAATGTAATNAATATGTGACAG 195 10 c t GCATTGGCCTGANGGATAGGCTGCT 196 10 c a GTAATCTAGCCANAACAATGGTTGC 197 10 c t GTTTGTAAATTTNGTGGATTGAAAG 198 10 c a TAAAGGAAAATANTTGAAGTGTTGG 199 10 g a CCCAGGAATTTCNAAAGGGAGCACA 200 10 c g GGAGTAGAGAAANACAACCTCAATA 201 10 g a TAAAAGGCAGTANGAAGGCAGTCCA 202 10 c a TTCTGCTGGAAANTTAGGGTGATCA 203 10 g t TTTCCCCTGTCANTTTAGCAATCAA 204 10 c t TCCTATATGGTGNCCCAAATTCTTA 205 10 c a GCCTCCTTTCAANCCTGGTGAGAAG 206 10 a g GAAATGTTCCCANGTCCAGCCATGA 207 10 t a TTTTAGCGAGGGNTCATTCGTTCAT 208 10 c t ATCATAAAAAATNGCCACTCGAGAA 209 10 t a TGAAAGCAACCANGGGTCTCTCATC 210 11 a g ATTTTGGTAAACNGGACCAGCATTT 211 11 t g TCCAATTCATGANGAAAGCCTAAGT 212 11 t c GAGCTTTTCCCANGTATGATCTGAC 213 11 g c CTAGATCTCTTANCAGTTTAATCCT 214 11 c t CAAACTTTGACTNTTGGTACTAAGA 215 11 t c CATCATTGGACANCATGAAATATGT 216 11 t c ATGAGGAAAATTNGGTACATTCATT 217 11 g c AAGTCATTCACANACACAAGTGATT 218 11 t c TGACTAAAAAGANTGAGCGTTTGTG 219 11 t c ACCTAATATCTANGAAGCCAATTGT 220 11 a g TCAGGGATCATANCACTGACAAAAG 221 11 g a ACTAAGATGCTGNGAAGACTGCAGG 222 11 a g TTGCACGGGAGCNGTTACAACATTT 223 11 c t GCATATCAGAAANGTATGACCACAA 224 11 t c TGAAACCAAGTTNGTACTCTTGGCT 225 12 t c ATTTAATTTGTANTCTTTCGGAAAT 226 12 c t AAATACTGCTTANGTAACTTAAGAG 227 12 a g AAAGTCTCTTTCNTATTAGCTAAAC 228 12 g a GGCCTAAAACCANCCACTTTATATG 229 12 g a TGGCTTCCAAGANTCCCCTGGTCAG 230 12 c g TTTTCATTGATANAAGGGTGAGCCA 231 12 t c AAAGCAGCAAGTNTGGCCATCTAGA 232 12 c t ATTCTGCAGGGANCATGGCCAGTTT 233 12 t c AGATAAACCTTTNACCACGTCTAGA 234 12 c t CAAACAGCTTTANGAAAAGTTTTAA 235 12 c t GTCAGGCAATTANGAGTACTAGGAG 236 12 a g TAATGCTATTTCNTACTATACAACT 237 12 a g GATAACCAAATCNTTTTTCGGATTT 238 12 g a AAACTTAACTGCNTTCTCAAATAGT 239 12 a g GATTTGATCCTTNTAAATTCCATAG 240 12 g a TTGCCTTTGGGANGTTCTTTGAGTT 241 12 t c TATCCTCAAATTNGGTCACTCAGGT 242 13 g c AGCACTTTGTTTNAATGAAACTATA 243 13 a c TTCTTGTGTCTCNACATTTTGTATG 244 13 c t TATTGGTTCAGANACTATTCGAAAT 245 13 a g CAATTGCAGAGANGTTTTCAAATGA 246 13 t g TAGATGTGACTGNTTCATTTAGCCA 247 13 t c TGATTCCACCATNATCTATAGCTCC 248 13 t c TGGGATGTATACNGTGAGTCACTAA 249 13 g t GAGTCTACCATTNTATTGGGTACAT 250 13 g a AACTTCAGAATANTTCAATTACCCT 251 13 g t AAGTCTTTTCCTNTTGAATACCATC 252 14 a g ACATTATGGTATNAACTTTGGCTGC 253 14 t c ATGGCTTAATCANAAGGAACTACAT 254 14 a t TCCCTACCTGAANCAACCCAGTGCA 255 14 g t AACTGCTACATTNGGAGCTTTCTGA 256 14 a g GGTTTGACTGCCNACGATGCTAAGA 257 14 c t TACAAAGTAGTGNAGCTGTACATCA 258 14 c t TCTCAGGAGAAGNGGCCCTTCTGAT 259 14 c t ATTGCAAACTTANGATATTCACAAA 260 14 g a GTGCTTGCCTCCNCTCTATCGGGCG 261 15 t c GATGCACGATACNAGAAATAAGCAT 262 15 g a ATCGCCTTGATANAAATATGATATG 263 15 c t CTACTGCTTCATNGCCCTCTAGTAC 264 15 t g TTGTTGTGCGTGNCTTGGATAGCAA 265 15 g a ACCTGTGCGTGCNAAACCCATGGCA 266 15 g a TGCGGGACCTGCNAAAATGTATCCC 267 15 g a GTGTTTTTAATCNTAGCTCTTTACT 268 16 a g ACAGTAACAATCNATCATTATGAGC 269 16 g a TTTTTACTTCCCNTCAAATCACAAG 270 16 t g ACCATTGAGAGGNTCCCCTTAGCCA 271 16 c t TGTTATTTTATCNGATTGAATTGTG 272 16 g a ATTTCGTATTTTNAATGCCCCACAA 273 16 a g CCATGAAAGATGNCTCCAGAAACTT 274 16 t c TACTGACCGTCCNGACGCTTTCAGT 275 16 g c ACTTTGTCACATNAAACAAGATGAG 276 16 c t CTTTGAAAACTGNGGGATGAGTTAG 277 17 c t TCTGACTCAATCNGCCTGTCTTTAG 278 17 t c CAGGAGACAGCTNGGGGTCACGGCG 279 17 g c CTGTCTCTACCANGTAACACATGAC 280 17 g a CTCGGTCTTGACNGTCTGAATTACT 281 17 g a TCCAGACAAAGGNATCAGTGCAAGC 282 17 t c TCTCCTATTTGTNCCATGGCAGTTA 283 17 c a GTTACTGACGGGNTTTAGCCATTAC 284 17 a g TTACTTTTCACANTCTCTCTAACAT 285 17 a g GGTTCTGAGAGCNCCACAAGGAAGA 286 18 c g TATCTTAGCCTANTAGAATGGAATC 287 18 a g TTGAGGGTGTGANTTTTCTGTATCC 288 18 g c TACTTTGTCCCTNTCATAGAACCTG 289 18 t a GTGCATTCTTCANACTGATTTGGGA 290 18 g a AGCAGGCTAAAGNTTTCACTGAAGT 291 18 a g ATTATCATTTGCNTAAGCCTCTCAT 292 18 g a CATACACTTCCANATCTTCTGTAGC 293 19 c t AATGATAAAAGANGACCCATGCCTT 294 19 a g CAATCTAATGCCNCAAGAAAAAATA 295 19 t c TGTTATTCCAACNCTGAACACATCA 296 19 a g TGACTGAGAGTANTGGACACAGTTT 297 19 g a GACACGCTAGACNAAGGGCGTCCAT 298 19 a c TGGGAATGTAATNGGCAGTTTAAGA 299 19 t c GACTTGAAAAAANCCAGACTTTTGA 300 19 c t AGAGGAACAAAANGGTAAGTAATTA 301 20 t c CCAAAACTCTTANAAATTCTATGGT 302 20 a c ACGAAAATCATANGACTCTACGGAA 303 20 a g CAAATTTCCACTNTCCCGAGAAGGT 304 20 c g AAAGTCATTGTTNTCAAATGGGATG 305 20 a g TATCTTTAAGCANTTTAGCAAGTAG 306 21 a g GATGATTACAGTNGTCGTAGTTCCC 307 21 c t AGTAAATAGCTCNTTTCTTTGTAGA 308 21 g a AGTCCTTGAAGANTGATCATAAAAA 309 22 g t GCGGACCTGAGTNACCTCATGGAAC 310 22 g a ATCAGATGACCANGAATTGAGAGAC 311 22 a g CTACAGAGGTACNTGCATAGGTCCA 312 22 c t TTTTTCTATAGANGGCCAGCACTGG

[0052] As indicated above, the genetic markers can include SNPs, microsatellites, or the like. A SNP is a single nitrogenous base position in the DNA of organisms that is variable, and typically arises due to substitution of one nucleotide for another at the polymorphic site. To illustrate this concept, FIG. 3B shows genomic sequences 306 and 308 corresponding to relatively short regions of two chromosomes, each having the same three SNP positions. Each SNP position is bi-allelic, generally exhibiting one of two alleles. In this case, the left-most depicted SNP has an A allele in sequence 306 and a C allele in sequence 308. Additionally, the two right-most SNPs have T alleles in sequence 307 and G alleles in sequence 308. As shown in FIG. 3B, the region circled at location 310 corresponds to a haplotype block, which is a contiguous region of sequence that exhibits a reduced set of observed allele combinations in comparison to all possible allele combinations. Haplotype blocks reflect descent from a single ancient ancestral chromosome and result in reduced genetic variability. As such, SNPs within a haplotype block tend to be inherited together. Thus, the only SNP allele combinations that would commonly occur for haplotype block 310 are A-T-T and C-G-G.

[0053] Turning again to FIG. 2, at 200, a DNA sample is obtained from the individual according to any known method. For example, a sample of saliva or blood can be collected from the individual.

[0054] Next, at 202, a polymerase chain reaction (“PCR”) or other amplification technique is used to amplify the DNA sample at various genomic regions. Each of these various regions preferably contains one of the multiple markers chosen to identify differences in ethnicity.

[0055] In one example, PCR is used to amplify the DNA sample at 312 regions containing the 312 above-mentioned genetic markers. For each marker, two primers are provided as well as the nucleotide monomers, polymerase and other components commonly employed in PCR.

[0056] As is well-known, the combined mixture is heated to a “melting” temperature (e.g., ninety-five degrees Celsius) to denature the DNA strands in the sample. After denaturing the DNA strands, the mixture can be cooled to an “annealing” temperature (e.g., 37 degrees Celsius) to allow the primers to hybridize with complementary portions of the single-stranded DNA in solution. FIG. 3A shows a nucleic acid sequence 300 to be amplified, that includes a marker 302. As shown, a primer 304 has hybridized with nucleic acid sequence 300. Next, the mixture is heated to 72 degrees Celsius to allow the polymerase to “extend” the complementary region beyond the end of primer 304. A different primer works from the opposite end of a nucleic acid sequence complementary to nucleic acid sequence 300. The cycle of denaturing and hybridizing can be repeated to produce an exponentially increasing number of amplified DNA strands. A more detailed description of the PCR can be found in various textbooks, such as Sambrook, et al., Molecular Cloning: A Laboratory Manual (Cold Spring Harbor Laboratory, New York) (2001); Innis, et al., PCR Applications: Protocols for Functional Genomics (Academic Press) (1999); and Newton, C. R. (ed.), PCR (John Wiley & Sons Ltd.) (1995), which are incorporated herein by reference in their entirety for all purposes. Further descriptions of PCR methods may be found in U.S. patent application Ser. No. 10/042,406, filed Jan. 9, 2002; U.S. patent application Ser. No. 10/042,492, filed Jan. 9, 2002; U.S. patent application Ser. No. 10/236,480, filed Sep. 5, 2002; U.S. patent application Ser. No. 10/174,101, filed Jun. 17, 2002; and U.S. patent application Ser. No. 10/341,832, filed Jan. 14, 2003, all of which are incorporated by reference in their entirety for all purposes.

[0057] As described above, PCR is performed for each of the various genetic markers (e.g., the 312 SNPs identified herein). In the simplest approach, PCR is performed in separate a vessel for each of the markers. Alternatively, and more efficiently, PCR can be multiplexed, such that several markers are amplified simultaneously in a single reaction vessel. In certain embodiments, at least about 5 to 100 markers are amplified in a single PCR reaction; in other embodiments, at least about 10-80 markers are amplified in a single PCR reaction; in still other embodiments, at least about 20-60 markers are amplified in a single PCR reaction. This is accomplished by exposing a single sample to multiple primer pairs, one pair for each region of DNA to amplified. Multiplexing can greatly enhance the sequencing speed for the various sequences, but multiplexing should be performed with care to avoid interference between the various sequences during the PCR. Accordingly, the markers and primers chosen for multiplexing can be selected to reduce the chance of interference between the sequences to be amplified simultaneously.

[0058] After amplifying the DNA at each of the genetic markers, the amplified DNA is pooled together into one sample per individual at step 204. At 206, this pooled DNA sample is tagged with a fluorescent reporter or other signal group by standard biochemical methods and applied to a DNA array. DNA arrays are typically made from DNA probe wafers that include high-density arrays of DNA probes placed on a glass wafer. These wafers are typically made using processes adapted from the semiconductor manufacturing industry. Such wafers are diced into chips, which are available from, for example, Affymetrix, Inc. of Santa Clara, Calif. In this case, the probes are chosen to identify the presence of the various alleles for each of the genetic markers. A chip composed of such probes is sometimes referred to as a “stratification chip.”

[0059] After the pooled DNA sample is applied to the DNA array, the sample and chip can be incubated. During incubation, segments of the pooled DNA sample can hybridize with complementary sequences of probes on the DNA chip. By evaluating which probes hybridize to segments of the pooled DNA sample, it is possible to determine what marker alleles are present in the DNA sample.

[0060] Thus, at 208, once segments of the DNA sample have hybridized with complementary sequences on the wafer, the DNA sample can be genotyped. More particularly, after segments of the DNA sample have hybridized with complementary probes on the wafer, any unbound DNA strands can be washed from the wafer. The wafer is then scanned to detect which of the probes on the DNA wafer have hybridized with the DNA sample. Typically, the DNA sequences are tagged with a fluorophore so that they will fluoresce under certain excitation conditions and, hence, be detectable to a laser scanning device. There are many different fluorophores available for labeling nucleic acids that are well known in the art, including, but not limited to, fluorescein and rhodamine. Because the identity and position of each probe on the DNA chip is known, the allelic values for each of the markers can be obtained for the individual, based on which of the probes hybridized with the DNA sample.

[0061] Although the present example describes using genomic DNA samples with a particular set of genetic markers, it should be recognized that the techniques of the present invention can be also used to characterize any number and type of bi-allelic or multi-allelic genetic markers in nucleic acid sequences derived from any organism, such as an animal, human, insect, or bacterium. In addition, although the present example describes genotyping by using DNA arrays, it should be recognized that other methods can be used to genotype individuals in the case and control groups. Generally, suitable techniques may utilize, for example, enzymatic, electrophoretic, chromatographic, or physical methods for discriminating allelic variants. Detection methods for genotyping may involve, for example, fluorescence detection, fluorescence resonance energy transfer, fluorescence polarization, electrochemical detection, mass spectrometry, or atomic force microscopy.

[0062] With reference to FIG. 4, an exemplary chart showing allele counts in case and control groups is shown for each of the 312 SNPs discussed above with regard to FIG. 2. This chart can be constructed from the results of genotyping each member of the case and control groups at 102 of FIG. 1. As shown, column 400 uniquely identifies each of the 312 SNPs. Column 402 lists the number of chromosomes from individuals in the case group having allele X for each of the respective markers. Column 404 lists the number of chromosomes from individuals in the case group having allele Y for each of the respective markers. Similarly column 406 lists the number of chromosomes in the control group having allele X for each of the respective markers and column 408 lists the number of chromosomes in the control group having allele Y for each of the respective markers. As shown, each of the case and control groups includes 100 individuals. The DNA samples taken from each of the 100 individuals include diploid cells having two sets of chromosomes. Each individual was genotyped for these two sets of chromosomes, thereby producing a total of two alleles per individual for each marker. Thus, for the 100 individuals in each of the case and control groups, a total of 200 alleles are included in the chart for each marker. If haploid cells had been used, only one set of chromosomes would be available for genotyping, and a total of 100 alleles would be included in the chart for each marker.

[0063] From the information in columns 402, 404, 406, and 408, a chi-squared statistic and corresponding p-value can be calculated for each of the 312 SNPs, which indicates the probability of a more extreme outcome if the case group and control group are matched. Higher p-values indicate relatively closely matched allele frequencies in the case and control groups, while lower p-values indicate relatively unmatched allele frequencies. Accordingly, if the p-values are consistently low, there is a strong likelihood that the case and control groups are unmatched.

[0064] While a single marker is not sufficient to draw a conclusion about the similarity of the population structures of a case group and a control group, it contributes to such a conclusion. For instance, SNP 1 in the table has very similar frequencies in the two groups and a correspondingly large p-value. On the other hand, SNP 2 has a fairly large difference in allele distribution in the two groups and has a p-value of only 0.02, indicating it is fairly unlikely to see such a large difference by chance. Because a large number of markers are analyzed together, it is not unlikely that a fairly small p-value will occur for one or another marker by chance.

[0065] With reference to FIG. 5, shown is an exemplary “Q-Q” plot illustrating observed and expected distributions of chi squared statistics for 312 markers. The positions of the data points along the Y axis represent the observed values ranked in order from smallest to largest. The positions of the points along the horizontal axis represent an equal number of values calculated to conform to the ideal chi squared distribution. If the observed and expected distributions are similar, then the plot should have a slope close to 1. If case and control groups are not well matched, the expectation is that a plot of this type will show a slope greater than 1, i.e., an excess of large chi squared statistics, corresponding to an excess of small p-values. Plot 500 indicates a distribution of chi squared statistics for a study where cases and controls are not well matched; the slope of the data is clearly greater than one. Plot 502 shows typical results for matched case and control groups; the slope of the data is very close to one.

[0066] With reference to FIG. 6, an exemplary table showing various probabilities for case and control groups is shown. This is essentially a tabular depiction of the plot presented in FIG. 5. Thus, the table can be constructed from the chart shown in FIG. 4. As shown in column 600, the table includes two rows, one for the expected frequency distribution and the other for the observed frequency distribution. Column 602 includes the number of markers having a p-value less than 0.1, column 604 includes the number of markers having a p-value less than 0.01, and column 608 includes the number of markers having a p-value less than 0.001. As described above, a uniform distribution of p-values (i.e., roughly 50% of markers having p-values less than 0.50, 10% less than 0.10, 1% less than 0.01) indicates that the case and control groups are matched. But an excess of smaller p-values indicates that the case and control groups are not matched. The information contained in this table or in a graph in FIG. 5 can be used to determine whether the difference between the observed and expected frequency distributions is acceptable.

[0067] Specific statistical criteria for determining that groups are sufficiently matched will necessarily depend on details of each study design. The methods of the present invention can be used for a broad range of different study designs, each with their own criteria for determining whether or not two groups are well matched. Factors that will influence these criteria include, but are not limited to, the number of individuals in the study, the magnitudes of other sources of experimental error, and the tolerance for false positives. For example, the groups might be sufficiently matched if the expected magnitude of spurious allelic differences due to population structure differences between the groups is small compared to other sources of error in the experiment; or, if the expected increase in false positive rate due to those population structure differences is small compared to the false positive rate expected in the absence of the population structure differences.

[0068] As indicated in the discussion of FIG. 1, when the separation of the expected and observed distributions of allelic differences exceeds a threshold, one should adjust the composition of the case and/or control group. See blocks 108 and 114. This may be accomplished by adding or subtracting members from the groups. To do this effectively, one should understand the population structure of the groups. This may be accomplished with stratification analyses.

[0069] With reference to FIG. 7A, an exemplary stratification table is shown. Column 700 represents the fraction of a particular ancestry represented in a population. In one example, the population is composed of individuals having some fraction of Native American ethnicity and some fraction of Caucasian ethnicity with column 700 representing the fraction of Native American ancestry for an individual in a case or control group.

[0070] The first row of the table shown in FIG. 7A includes individuals that are eighty to one hundred percent Native American ancestry. The second row includes individuals that are sixty to eighty percent Native American ancestry (or twenty to forty percent Caucasian ancestry). The third, fourth, and fifth rows similarly indicate a percentage of Native American ancestry. Column 702 represents the number of individuals in the case group having a particular percentage of Native American ancestry. Similarly, column 704 represents the number of individuals in the control group having a particular percentage of Native American ancestry. For instance, five people in the case group have between eighty to one hundred percent Native American ancestry.

[0071] The above stratification table can be constructed using the data obtained from genotyping case and control groups for multiple markers, as described above with regard to operation 102 in FIG. 1. In particular, this data can be input into an algorithm that performs a cluster analysis. The goal of a cluster analysis in accordance with this embodiment is to group individuals from the case group and control group based on similar allele patterns. Generally, a clustering algorithm will attempt to maximize differences between groups, while minimizing differences within groups. Various such algorithms are suitable for use with this invention.

[0072] In one embodiment, the genotypes for individuals of the case group or control group is input for analysis by a computer program called “Structure,” which is available from the author's web site at http://pritch.bsd.uchicago.edu/. This program is described in Pritchard et al., “Inference of Population Structure Using Multilocus Genotype Data,” Genetics (June 2000) vol. 155, 945-959, which is incorporated herein by reference for all purposes. The number of desired groupings, as shown in column 700 of FIG. 7A, is input into the program. As shown, column 700 includes five groupings based on the percentage of Native American ancestry.

[0073] The “Structure” program analysis estimates the fraction of an individual's genome that seems to come from a certain homogeneous ancestral population. More specifically, the Structure program uses the genotypes (the allele pairs for each marker in each individual) to cluster individuals having similar allele patterns. These clusters are then output as N groups, where N is the number of desired groupings input to the program. As shown in FIG. 7A, the output can be expressed as clusters of people having a particular fraction of a specified ancestry. It should be recognized that this output can be presented in any form, such as a table, chart, or list.

[0074] As shown in FIG. 7A of the present embodiment, the distribution of Native American ancestry differs between the case group and control group. Specifically, the case group includes five individuals having eighty to one hundred percent Native American ancestry, whereas the control group includes thirty individuals having the same fraction of Native American ancestry. Based on this comparison, along with the rest of the data in the table, the control group has a greater proportion of Native American ancestry. If the difference between observed and expected frequency distributions for the case and control groups is not within an acceptable range, as determined in accordance with 108 of FIG. 1, then the composition of the case and control groups can be adjusted. Typically, a determination that the case and control groups are unbalanced is made prior to applying a stratification analysis, such as one giving the results depicted in FIG. 7A.

[0075]FIG. 7B is an adjusted version of the exemplary stratification table shown in FIG. 7A. As shown, a total of fifty individuals were removed from each of the case and control groups. In particular, from the case group, twenty-five individuals having zero to twenty percent Native American ancestry were removed, and twenty-five individuals having twenty to forty percent Native American ancestry were removed. In addition, from the control group, twenty-five individuals having eighty to one-hundred percent Native American ancestry were removed, and twenty-five individuals having sixty to eighty percent Native American ancestry were removed. After removing these fifty individuals from each of the case and control groups, the frequency distribution of individuals with Native American ancestry in the case and control groups is similar from the perspective of the clustering algorithm, as shown in FIG. 7B. These groups are now matched with regard to Native American ancestry. If the recast groups now produce a relatively small difference between the expected and observed distributions of allele differences, then they can be used in an association study. See operations 114, 108, and 106 of FIG. 1. As discussed above, conducting an association study using these matched groups can increase the chance that any difference in allele frequencies between the groups is causally related to the phenotypic trait of interest, and reduce the chance that this difference is related to population structure differences between the two groups.

[0076] The case and control groups can be adjusted according to a variety of methods. The stratified approach depicted in FIG. 7B is only one such method. It can be problematic when there is a limited pool of potential members for the groups. It may eliminate too many individuals, so that the groups no longer represent a statistically significant sampling. One method that addresses this issue continually recomputes the mean frequencies of the case and control groups as it gradually adjusts these groups until they have equivalent mean allele frequencies for the genetic markers, indicating that the population structures are similar and the groups are appropriately matched. The adjustment comprises selectively removing “outlier” individuals from one or both groups. This process is depicted in FIG. 8, where an exemplary graph includes mean curves for case and control groups. The vertical axis represents the statistical mean population structure for the remaining individuals as derived from individual ethnicities calculated by the clustering algorithm. Stated another way, this mean represents the “average” population structure represented across the case or control group.

[0077] As shown, the horizontal axis represents the number of individuals in the group. Accordingly, as the number of individuals increases, the mean is recalculated for the new total number of individuals. Furthermore, the individuals are added along the horizontal axis in either ascending or descending order according to the individual's percentage of a particular ethnicity.

[0078] In the present example, the vertical axis represents the mean percentage of Native American ancestry (or whatever population structure component is appropriate for the study at hand) and the horizontal axis represents the number of individuals in a group. In this example, curve 802 represents the control group, curve 800 represents the case group. In the present example, cases tend to have a higher proportion of Native American ancestry than controls, so for matching we will generally want to select the cases with relatively low degrees of Native American ancestry, and the controls with relatively high degrees of Native American ancestry. Curve 800 shows the highest attainable mean degree of Native American ancestry that can be obtained for a given number of controls. Curve 802 shows the lowest attainable mean degree of Native American ancestry that can be obtained for a given number of cases. Balanced study designs should choose a number of cases, and a number of controls, for which the same degree of Native American ancestry can be obtained. Point 804, at the intersection of curves 800 and 802, represents one such balanced design, which would be optimal if equal numbers of cases and controls are desired.

[0079] The composition of the two groups need not always be chosen fall at the point of intersection. In fact, this might not be desirable. In some studies, it may be significantly easier to recruit controls than cases, and it may be better to choose a mean population structure for the case and control groups that yields a larger number of controls than cases. Graphically, this is represented by choosing sample sizes as the intersections of curves 800 and 802 with a horizontal line at the chosen mean population structure.

[0080] These graphs actually consist of discrete points corresponding to integer numbers of individuals and there will generally not be a point at which the means of the case and control groups are absolutely identical. Yet there will be a pair of points from the two curves where the mean values come closest. So one may chose these two closest points as the matching mean. Although a specific means matching technique is outlined here, it should be recognized that the case and control groups can be adjusted according to a variety of methods, depending on the application. If the analysis indicates that the case and control groups have substantial contributions from more than two ancestral populations, then a similar procedure of removing the most extreme individuals can still be employed.

[0081] A third matching method can be employed when the case and control groups are defined using ranges of a quantitative measurement. Rather than defining cases and controls, and then selecting subsets that are matched, the measurement can be adjusted to remove the effect of population structure anomalies, and then cases and controls can be selected based on the adjusted phenotype. One appropriate adjustment method involves using a multiple linear regression or general additive model to measure the influence of the estimated genetic population structure parameters on the measurement. For each experimental subject, the model is used to determine a fitted value representing the expected mean measurement for individuals with the same population structure. Subtracting these fitted values from the observed measurements, gives values that are “standardized” or corrected for the influence of population structure. Criteria for defining cases and controls can then be defined in terms of their adjusted measurements. This method can easily be applied regardless of the number of ancestral population clusters, as each cluster is simply represented by an additional independent variable in the regression analysis.

[0082] As should be apparent, embodiments of the present invention employ processes acting under control of instructions and/or data stored in or transferred through one or more computer systems. Embodiments of the present invention also relate to apparatus for performing these operations. Such apparatus may be specially designed and/or constructed for the required purposes, or it may be a general-purpose computer selectively activated or reconfigured by a computer program and/or data structure stored in the computer. The processes presented herein are not inherently related to any particular computer or other apparatus. In particular, various general-purpose machines may be used with programs written in accordance with the teachings herein. In some cases, however, it may be more convenient to construct a specialized apparatus to perform the required method operations. A particular structure for a variety of these machines will appear from the description given below.

[0083] In addition, embodiments of the present invention relate to computer readable media or computer program products that include program instructions and/or data (including data structures) for performing various computer-implemented operations. Examples of computer-readable media include, but are not limited to, magnetic media such as hard disks, floppy disks, magnetic tape; optical media such as CD-ROM devices and holographic devices; magneto-optical media; semiconductor memory devices, and hardware devices that are specially configured to store and perform program instructions, such as read-only memory devices (ROM) and random access memory (RAM), and sometimes application-specific integrated circuits (ASICs), programmable logic devices (PLDs) and signal transmission media for delivering computer-readable instructions, such as local area networks, wide area networks, and the Internet. The data and program instructions of this invention may also be embodied on a carrier wave or other transport medium (e.g., optical lines, electrical lines, and/or airwaves). Examples of program instructions include both machine code, such as produced by a compiler, and files containing higher level code that may be executed by the computer using an interpreter. Further, the program instructions include machine code, source code and any other code that directly or indirectly controls operation of a computing machine in accordance with this invention. The code may specify input, output, calculations, conditionals, branches, iterative loops, etc.

[0084] The various method operations described above may be implemented in whole or part on one or more computer systems. Often, it will be convenient to employ two or more computer systems to implement the invention. As an example, one system may serve to genotype the members of the case and control groups, while a different system determines the distribution of alleles within the groups and rebalances the groups if necessary. Such systems may share information via a computer network. In addition, separate computer program products (including their machine readable media) may be employed to house the program instructions for separate operations of the invention.

[0085]FIGS. 9A and 9B illustrate a computer system 900 suitable for implementing embodiments of the present invention. FIG. 9A shows one possible physical form of the computer system. Of course, the computer system may have many physical forms ranging from an integrated circuit, a printed circuit board and a small handheld device up to a very large super computer. Computer system 900 includes a monitor 902, a display 904, a housing 906, a disk drive 908, a keyboard 910 and a mouse 912. Disk 914 is one example of a computer-readable medium used to transfer data to and from computer system 900.

[0086]FIG. 9B is a block diagram of certain logical components of computer system 900. Attached to system bus 920 are a wide variety of subsystems. Processor(s) 922 (also referred to as central processing units, or CPUs) are coupled to storage devices including memory 924. Memory 924 includes random access memory (RAM) and read-only memory (ROM). ROM acts to transfer data and instructions uni-directionally to the CPU and RAM is used typically to transfer data and instructions in a bi-directional manner. Both of these types of memories may include any suitable computer-readable medium, including those described above. A fixed disk 926 is also coupled bi-directionally to CPU 922; it provides additional data storage capacity and may also include any of the computer-readable media described below. Fixed disk 926 may be used to store programs, data and the like and is typically a secondary storage medium (such as a hard disk) that is slower than primary storage. It will be appreciated that the information retained within fixed disk 926, may, in appropriate cases, be incorporated in standard fashion as virtual memory in memory 924. Removable disk 914 may take the form of any of the computer-readable media described below.

[0087] CPU 922 is also coupled to a variety of input/output devices such as display 904, keyboard 910, mouse 912 and speakers 930. In general, an input/output device may be any of: video displays, track balls, mice, keyboards, microphones, touch-sensitive displays, transducer card readers, magnetic or paper tape readers, tablets, styluses, voice or handwriting recognizers, biometrics readers, or other computers. CPU 922 optionally may be coupled to another computer or telecommunications network using network interface 940. With such a network interface, it is contemplated that the CPU might receive information from the network, or might output information to the network in the course of performing the above-described method steps. Furthermore, method embodiments of the present invention may execute solely upon CPU 922 or may execute over a network such as the Internet in conjunction with a remote CPU that shares a portion of the processing.

EXAMPLES

[0088] To test and compare the population structures of a case and a control population prior to performing an association study, 312 SNPs from a subset of individuals from each population were genotyped. Multiplex PCR was used to amplify genomic regions containing the 312 SNP loci, and a different primer pair was required for each SNP locus. The 312 primer pairs required to amplify the genomic regions containing the 312 SNP loci were pooled such that 13 primer pairs were included in each multiplex PCR. Thus, a total of 24 multiplex PCRs were required to amplify the 312 SNP loci for each individual to be tested.

[0089] The pooled primer pairs were diluted to a final concentration of 2.5 μM with TE resulting in 10.34 ml of a pooled primer stock solution. Then, for one pooled primer stock solution, 114 μl was aliquoted into each of the wells in a predetermined region on a multi-well plate (“Primer Stock Plate”). This was repeated for each of the pooled primer stock solutions such that aliquots of each occupied different regions on the Primer Stock Plates. Thus, a total of 24 regions were required to hold the aliquots from the 24 pooled primer stock solutions, and these regions were contained on a total of six multi-well plates (four regions per plate). The Primer Stock Plates were stored at −20° C. until required for preparation of PCR Plates, as described infra.

[0090] Prior to use, 2 μl from each well of a Primer Stock Plate was transferred into a well in a corresponding location on a second multi-well plate (“PCR Plate”). This was repeated for the same Primer Stock Plate for 49 additional PCR Plates. The transfer from a single Primer Stock Plate to 50 PCR Plates was repeated for the other five Primer Stock Plates. The resulting PCR Plates were stored at −20° C. until required for carrying out PCR, as described infra.

[0091] Each DNA sample to be genotyped was diluted with water to a final concentration of 2.5 ng/μl. Buffer for PCR was prepared as follows. For each PCR reaction: PCR buffer components Volume Water 2.25 μl 10X AK2 1.47 μl 1M Tricine 0.38 μl 10X Enhancer 0.67 μl 100% DMSO 0.47 μl Total PCR buffer 5.24 μl

[0092] After preparing the PCR buffer, dNTPs and Titanium Taq polymerase (Clontech (BD Biosciences), Palo Alto, Calif.) were added, in that order, to create the “PCR cocktail” as follows:

[0093] For each PCR reaction: To be added to PCR buffer Volume 25 mM of each dNTP 0.26 μl  50X Titanium Taq (Clontech) 0.5 μl Total PCR cocktail 6.0 μl

[0094] The volume for the PCR buffer was scaled up depending on how many PCR reactions were to be performed. Likewise, the amounts of dNTPs and Taq polymerase were also scaled up.

[0095] Then, for each individual DNA sample, 100 μm of the diluted DNA was added to 150 μl of PCR cocktail to create a Master Mix, 10 μl of which was then added to a set of wells on PCR plates, each of which contained 2 ul of one of the 13 pooled primer stock solutions. In this way, 24 multiplex PCRs were prepared for each individual DNA sample. Once each individual DNA sample was combined with PCR cocktail and each of the pooled primer stock solutions, PCRs could be performed on a thermocycler. The PCR cycle conditions were as follows: Temperature Time Number of cycles 96° C.  5 min 1 96° C. 30 seconds 10 58° C. (−0.5° C. per cycle) 30 seconds 65° C. 60 seconds 96° C. 10 seconds 40 53° C. 30 seconds 65° C. 60 seconds 65° C.  7 minutes 1  4° C. indefinitely

[0096] After the PCR was complete, the plates were centrifuged briefly at 1500 rpm and stored at −20° C. until required for pooling, as described infra.

[0097] Next, the products of the 312 PCRs for the 312 SNPs were pooled together for each individual from which a DNA sample was amplified. The PCR product pools were then diluted 1:25 with water. These diluted, pooled PCR products were stored at −20° C. until required for quantification, as described infra.

[0098] The quantification of the diluted, pooled PCR products was performed using PicoGreen dsDNA Quantitation Reagent (Molecular Probes, Inc., Eugene, Oreg.) in combination with a Cytofluor system (Applied Biosystems, Foster City, Calif.) or Spectraphor Plus (Tecan Instruments, Maennedorf, Switzerland) according to manufacturer's instructions. A DNA concentration of less than 10 ng/μl was indicative that the PCR had failed and the sample was not processed further. An acceptable DNA concentration was between 15 and 30 ng/μl. If the concentration was higher, then the DNA was diluted to adjust the average concentration to 25 ng/μl.

[0099] After quantification of the pooled PCR products, 10 μl of each was labeled with biotin (biotin stock solution=1 mM of a 1:1 mix of b-ddUTP and b-dUTP) using the following labeling mix:

[0100] Per 10 μl DNA sample Labeling Mix Component Volume 10X One-Phor-All Buffer   3.6 μl Biotin stock solution 0.0156 μl Water  22.32 μl Recombinant TdT (400 U/μl) 0.0625 μl Total Labelin Mix    26 μl

[0101] The volume for the Labeling Mix was scaled up depending on how many DNA samples were to be labeled. The One-Phor-All buffer, the biotin-labeled nucleotides, and the recombinant TdT were from Amersham Biosciences (Piscataway, N.J.), Enzo (Farmingdale, N.Y.), and Roche Diagnostics (Basel, Switzerland), respectively. The labeling reaction was performed on a thermocycler under the following conditions: Temperature Time 37° C. 90 minutes 99° C. 10 minutes  4° C. indefinitely

[0102] The samples were then stored at −20° C. until it was time to hybridize them to stratification chips. The hybridization buffer used was as follows: Hybridization buffer components Per chip Per plate 5M TMACL 60 μl  5640 μl  1% Triton X-100 1 μl 94 μl 5 nM b-948 oligo 1 μl 94 μl 10 μg/μl herring sperm DNA 1 μl 94 μl 1 M Tris, pH 7.8 1 μl 94 μl Total hybridization buffer 64 μl  6016 μl 

[0103] 64 μl of hybridization buffer was added to each labeled sample prior to denaturation at 99° C. for 10 minutes, after which the denatured samples were cooled to 50° C. Each oligonucleotide array chip (hereafter “chip”) was prewarmed in a 50° C. incubator. Then, 100 μl of a denatured sample was transferred to a chip. This process was repeated for all denatured samples. Chips containing denatured samples were transferred to a 50° C. hybridization oven and rotated at 25 rpm for at least 12 hours.

[0104] The hybridized chips were then stained, washed, and scanned on a laser scanner. The data from the scans was processed to reveal the genotypes of the 312 SNPs for the subsets of individuals from the case and control groups, and these genotypes were used to determine whether the population structures of the two groups was matched, as described in the Detailed Description supra.

Conclusion

[0105] Although the above generally describes the present invention according to specific exemplary processes, various modifications can be made without departing from the spirit and/or scope of the present invention. Therefore, the present invention should not be construed as being limited to the specific forms shown in the appended figures and described above.

1 313 1 9 DNA Human 1 atgatgatg 9 2 25 DNA Human 2 taccatcatt ttsgaattgt tcaga 25 3 25 DNA Human 3 ggcctagagt tayggcattt cactt 25 4 25 DNA Human 4 gagagttcaa tgygtaaaga tgccc 25 5 25 DNA Human 5 taattggggt ttygtaacta gctac 25 6 25 DNA Human 6 caattgctca tcragtccat gaaag 25 7 25 DNA Human 7 ggtacgcttc aaygttatat gcggt 25 8 25 DNA Human 8 gagatctcaa acyttaattt tactg 25 9 25 DNA Human 9 caagctgaac ctsaatgtag ctcca 25 10 25 DNA Human 10 gtgtcccact atwtaagaaa tgttt 25 11 25 DNA Human 11 ttaaccgtct gtrctctcta cacgg 25 12 25 DNA Human 12 tatatccaac cawctcttgg ctcta 25 13 25 DNA Human 13 cgtaggccgt aamctgatgc catga 25 14 25 DNA Human 14 cttacttttc acsttactac ttgca 25 15 25 DNA Human 15 tgagttatag agktgaatcc atgtg 25 16 25 DNA Human 16 gaaaaccatt ctmaattcca gttcc 25 17 25 DNA Human 17 ctaggagcta caratagttc caacc 25 18 25 DNA Human 18 caatgggaga ttsaggccta gagca 25 19 25 DNA Human 19 aaggtacata ttrggatgag atact 25 20 25 DNA Human 20 ttgataattt gaytaaagct gacct 25 21 25 DNA Human 21 actggctgcg cayggacaag tgtca 25 22 25 DNA Human 22 tcattcttac caytggtgct gaaaa 25 23 25 DNA Human 23 atttttcagc ttratttaac attgt 25 24 25 DNA Human 24 taatctttat tgyattctca ttggc 25 25 25 DNA Human 25 gacagtctgc aamaaaattt tctgg 25 26 25 DNA Human 26 tttaccaggt ccrccaagac tatga 25 27 25 DNA Human 27 tcacacaaag gcrtaatcat gaaaa 25 28 25 DNA Human 28 ggaattgtgc taratacaaa aatgc 25 29 25 DNA Human 29 acagaagtta agytaaacgt tctaa 25 30 25 DNA Human 30 aataacttcc gcrtaatgag taccc 25 31 25 DNA Human 31 ctggcttcag aastgatctt ttcct 25 32 25 DNA Human 32 gtatttgtct gartcataga attta 25 33 25 DNA Human 33 caagtcacat cargaagttg tggcc 25 34 25 DNA Human 34 aacggaacaa tawtacattc ctggg 25 35 25 DNA Human 35 ataagcagcc atmttattga gaagc 25 36 25 DNA Human 36 taacaaacat aaratttgca ttata 25 37 25 DNA Human 37 taaggagcta atrgccaata attac 25 38 25 DNA Human 38 ggcagggaac cartctttag aaact 25 39 25 DNA Human 39 ttcaaggaac ccrtgttgat aataa 25 40 25 DNA Human 40 ttatactaca gaygttcatt atgcc 25 41 25 DNA Human 41 gcagaatgcc ccrtccgtaa atgtc 25 42 25 DNA Human 42 tttgaatcag agragtgatt ttgaa 25 43 25 DNA Human 43 tctgcgatct ggmaatagag ctttc 25 44 25 DNA Human 44 atacctctcc agycacacat aataa 25 45 25 DNA Human 45 agtaatcact ttrtgtcaaa atgtt 25 46 25 DNA Human 46 tcactagatg caratttctt catgt 25 47 25 DNA Human 47 aatttcagca garggattat gatgc 25 48 25 DNA Human 48 taaaattttc cargctggag caatt 25 49 25 DNA Human 49 aacaatcgag gtwggcttta aagga 25 50 25 DNA Human 50 gttagcacag ttyatagcaa gtctt 25 51 25 DNA Human 51 attgcttggc acrttctcag aggtg 25 52 25 DNA Human 52 cgcttcttgc agrggaactt catgg 25 53 25 DNA Human 53 accatgttga garttgtgcc tagct 25 54 25 DNA Human 54 gcagaccaga gastgtcaat ttaag 25 55 25 DNA Human 55 acatcttaat gargtgctga cattt 25 56 25 DNA Human 56 ctgatatagg ccrtagtgtc aggac 25 57 25 DNA Human 57 catgagatgg ccrttttcca ggaga 25 58 25 DNA Human 58 ataacatcct gcyggttact gatca 25 59 25 DNA Human 59 ccctgggaac acrctactga gagcc 25 60 25 DNA Human 60 tactatgggg aasaacttgt cactt 25 61 25 DNA Human 61 aacttactgg aaygggaact tttca 25 62 25 DNA Human 62 gataccctta tayggcagaa cttta 25 63 25 DNA Human 63 ctgttgggaa acwcttcagt cacac 25 64 25 DNA Human 64 gggtacaatt agrtcttact catgc 25 65 25 DNA Human 65 caatttcgta cayttgaaag agaca 25 66 25 DNA Human 66 gccttacaga gcygtgattt tggct 25 67 25 DNA Human 67 aatcctgacg gtrggttcta caatt 25 68 25 DNA Human 68 tttcaagagg tgygaggaca aggcc 25 69 25 DNA Human 69 cattcctggc tgrtcgtaga caagg 25 70 25 DNA Human 70 gaatcagaag gcraaatgtt tgggc 25 71 25 DNA Human 71 aacgtggaac aasagtgaaa aaatg 25 72 25 DNA Human 72 gtgtttactc caraatacca gctta 25 73 25 DNA Human 73 aaagggtcag tcrttgaaac attgc 25 74 25 DNA Human 74 ccagtgcccg gcragtaacc aacgc 25 75 25 DNA Human 75 aagtgtgcat aaygtagaga ctcat 25 76 25 DNA Human 76 tgactttaga gcrtagtatt ttagc 25 77 25 DNA Human 77 taggtggcaa atygataccc tgagg 25 78 25 DNA Human 78 tgatttttgg atmggaaagg agact 25 79 25 DNA Human 79 gcgaggacct atsggatgtg taggc 25 80 25 DNA Human 80 catggcgctt tarcacaagt atgga 25 81 25 DNA Human 81 tctgaaacca tcscaggaat gatgc 25 82 25 DNA Human 82 ttctagtctc ctycccgggc ggtca 25 83 25 DNA Human 83 gctgagaatt tcmagtgtga tcggt 25 84 25 DNA Human 84 tggtttcttg caytgggagg gagac 25 85 25 DNA Human 85 tatgtaaaag caygtgtcat tatga 25 86 25 DNA Human 86 tcacattttc ttycaaaggc aagta 25 87 25 DNA Human 87 ttactgaaca aaktatcatc tcagg 25 88 25 DNA Human 88 tgaataatgc ctytagggtc tgaat 25 89 25 DNA Human 89 cactttacgg ctytcaccat tcaca 25 90 25 DNA Human 90 ctttgaaatc ttrtagttct gctgc 25 91 25 DNA Human 91 ttcctcactg taytgcttat tctct 25 92 25 DNA Human 92 gagcctggca taygaaacaa tttcc 25 93 25 DNA Human 93 gaacacaata acraaacaga tgatg 25 94 25 DNA Human 94 ctgggttgct tcytgtaaac ctgca 25 95 25 DNA Human 95 ctaaaagtaa atrtcggtat cagtg 25 96 25 DNA Human 96 tagatagcat gcrgcttcaa gaaga 25 97 25 DNA Human 97 cagcgatgtt caytggcggc ttatt 25 98 25 DNA Human 98 cactaatcaa gtrcactagc cctcc 25 99 25 DNA Human 99 ctttttacca ctraactctg gaatg 25 100 25 DNA Human 100 ttcaaatcat ccrcagactt gttca 25 101 25 DNA Human 101 tgttttctgg acrcatagct catgt 25 102 25 DNA Human 102 ctgggcaaat cawccattaa cactc 25 103 25 DNA Human 103 ttttggagga ccwcaatcat ggttc 25 104 25 DNA Human 104 attacctcct taygcaaatg accac 25 105 25 DNA Human 105 gaatcgtggg gcrttttggc agcct 25 106 25 DNA Human 106 acactacagt aayacctcta gccca 25 107 25 DNA Human 107 aaacatgatt atkctcctgc attga 25 108 25 DNA Human 108 ggaactggaa agmaacttcc atcag 25 109 25 DNA Human 109 tgtcaggcac ttyagggcat tgacc 25 110 25 DNA Human 110 ggagccatga garttattgc ggccc 25 111 25 DNA Human 111 tgtgctttct gaygcctacc tccaa 25 112 25 DNA Human 112 aagtggaggg cgytcattcc atcct 25 113 25 DNA Human 113 gaaatcatgt ccrccctttt ccagt 25 114 25 DNA Human 114 tacctattcg ccytccatga aacag 25 115 25 DNA Human 115 tgagatttcc taygatggaa gtgtg 25 116 25 DNA Human 116 ctgtttcctt tcyggttggt tcgtt 25 117 25 DNA Human 117 cgcagtacaa ggyttcccta gtagt 25 118 25 DNA Human 118 acagtatttg gayggctgac taaaa 25 119 25 DNA Human 119 ctaaaagtgg acragagcct taaaa 25 120 25 DNA Human 120 aaagcctcca cgsgacaaca gtttc 25 121 25 DNA Human 121 gagacctcaa agrttcacaa catga 25 122 25 DNA Human 122 tcactgcata taytaacata aaaac 25 123 25 DNA Human 123 tattattatc ccrttgtaaa tgttt 25 124 25 DNA Human 124 atattgtcac tgrtgccctt gattg 25 125 25 DNA Human 125 gcacctaacc atytgctgac gtggc 25 126 25 DNA Human 126 ttacaggttt caytttttta tcgtc 25 127 25 DNA Human 127 aaaagtttag gawcatagta aggtt 25 128 25 DNA Human 128 aaactctatg ctktggcctt tcata 25 129 25 DNA Human 129 cattatgaat tcyttcgtca ctgat 25 130 25 DNA Human 130 aaggcagagc acktttctgt ggttc 25 131 25 DNA Human 131 tttagaaata gcyggtgatt acaga 25 132 25 DNA Human 132 tacagaacct tasacagact acgta 25 133 25 DNA Human 133 cagagcttat tcsttctacc ttgtt 25 134 25 DNA Human 134 gcatgtctca carcattacg aatgg 25 135 25 DNA Human 135 tgcatagtaa tcyttcattc agcac 25 136 25 DNA Human 136 tagctacagt taycgattcc gctta 25 137 25 DNA Human 137 agtatttgtc aaytaatgct gttaa 25 138 25 DNA Human 138 aaggctttcc tgkaaaagta gctgt 25 139 25 DNA Human 139 tagcagcatt camgggactc aggtg 25 140 25 DNA Human 140 gcaatagcta atygagttcc tgatt 25 141 25 DNA Human 141 tactttgatt aawggctgat gatat 25 142 25 DNA Human 142 ttaaaatttg tcsgtgccaa tttag 25 143 25 DNA Human 143 tacctgtgta aakaaattga taaca 25 144 25 DNA Human 144 gtccaattag cartaagtgc catgc 25 145 25 DNA Human 145 cttttgttca ttkgataatc gggtg 25 146 25 DNA Human 146 gaatgtctgc tcrgttacaa cgtga 25 147 25 DNA Human 147 gcatgtattg tcyatccaaa aactt 25 148 25 DNA Human 148 aattcagacc acrcttaggg aatca 25 149 25 DNA Human 149 gtccacaaag gtytggaata taaaa 25 150 25 DNA Human 150 ttgtgatatt cckccaaagt aaaca 25 151 25 DNA Human 151 tctgtacctc atktacttgt agtct 25 152 25 DNA Human 152 actcaggtgc atycagagcc gaagg 25 153 25 DNA Human 153 agtcaatgct tayttaagct tattc 25 154 25 DNA Human 154 acatggtagc agraaatgag agcgt 25 155 25 DNA Human 155 gttataaagc ctytccaggt gcaga 25 156 25 DNA Human 156 tcaagtgcct gcyacaagta aatag 25 157 25 DNA Human 157 catgtataag ccraaagcta aaacg 25 158 25 DNA Human 158 cactcgagca tgyggcatta tttaa 25 159 25 DNA Human 159 atcagtcatt tcyggctctt tatgt 25 160 25 DNA Human 160 agccaaacca tayctagttt ccaaa 25 161 25 DNA Human 161 atgtgatact taygaattcc accag 25 162 25 DNA Human 162 gtacctctag acrtccatac agctt 25 163 25 DNA Human 163 acagctgagt garaacaaaa tggac 25 164 25 DNA Human 164 tacagtacag acrttgatga gacca 25 165 25 DNA Human 165 agtcttatct ttsggacaaa tggaa 25 166 25 DNA Human 166 tccaagcctc ccrgaatgaa acttt 25 167 25 DNA Human 167 ccacttctaa tasctttcac aagac 25 168 25 DNA Human 168 cgtaaactga gcwgacctgt accct 25 169 25 DNA Human 169 ctgtgttaaa ctyccagatg gcagt 25 170 25 DNA Human 170 cagctggaaa casgtctggg ctctt 25 171 25 DNA Human 171 gttaaccagc ctraatgcaa aaagt 25 172 25 DNA Human 172 aacagccaga gtycctgtaa gagca 25 173 25 DNA Human 173 ggcatacatc ttycttaacc tacat 25 174 25 DNA Human 174 ggtccaaaag tcstgctagg tatct 25 175 25 DNA Human 175 ggcaagacct caraataact taaag 25 176 25 DNA Human 176 atgcgtaggt tawggtccta gttca 25 177 25 DNA Human 177 gtgctacttt gamtgtgaaa ataca 25 178 25 DNA Human 178 ctcaggaaag aaytgccact tcgaa 25 179 25 DNA Human 179 atttgatgtg acygatagct ccaga 25 180 25 DNA Human 180 cagagccaaa aaygttgctc ttcca 25 181 25 DNA Human 181 atgctactga taygtaatca caatg 25 182 25 DNA Human 182 accctttcta ctrtactatc acagc 25 183 25 DNA Human 183 cagtgttctt tgrggttcca ctctt 25 184 25 DNA Human 184 ctagtgcttt caygatgccc ttagt 25 185 25 DNA Human 185 gttaccctta caygtggctg tttgc 25 186 25 DNA Human 186 ttctaactct cawttaagtg aggca 25 187 25 DNA Human 187 ctcacattac ccractttgg gccct 25 188 25 DNA Human 188 gccaatgttt agyggagata tttct 25 189 25 DNA Human 189 tgttcaagcc atygatatta ggttg 25 190 25 DNA Human 190 gtgtgatgct ctyttttgac ccaca 25 191 25 DNA Human 191 cttttctaat acygcaatat ttcaa 25 192 25 DNA Human 192 tgaaacttag gcrgaatagt aagta 25 193 25 DNA Human 193 tatcatggga ccrtcctata aggtt 25 194 25 DNA Human 194 tggagagagg ccrtttccta atcag 25 195 25 DNA Human 195 cctgaatgta atsaatatgt gacag 25 196 25 DNA Human 196 gcattggcct gayggatagg ctgct 25 197 25 DNA Human 197 gtaatctagc camaacaatg gttgc 25 198 25 DNA Human 198 gtttgtaaat ttygtggatt gaaag 25 199 25 DNA Human 199 taaaggaaaa tamttgaagt gttgg 25 200 25 DNA Human 200 cccaggaatt tcraaaggga gcaca 25 201 25 DNA Human 201 ggagtagaga aasacaacct caata 25 202 25 DNA Human 202 taaaaggcag targaaggca gtcca 25 203 25 DNA Human 203 ttctgctgga aamttagggt gatca 25 204 25 DNA Human 204 tttcccctgt caktttagca atcaa 25 205 25 DNA Human 205 tcctatatgg tgycccaaat tctta 25 206 25 DNA Human 206 gcctcctttc aamcctggtg agaag 25 207 25 DNA Human 207 gaaatgttcc cargtccagc catga 25 208 25 DNA Human 208 ttttagcgag ggwtcattcg ttcat 25 209 25 DNA Human 209 atcataaaaa atygccactc gagaa 25 210 25 DNA Human 210 tgaaaccaac cawgggtctc tcatc 25 211 25 DNA Human 211 attttggtaa acrggaccag cattt 25 212 25 DNA Human 212 tccaattcat gakgaaagcc taagt 25 213 25 DNA Human 213 gagcttttcc caygtatgat ctgac 25 214 25 DNA Human 214 ctagatctct tascagttta atcct 25 215 25 DNA Human 215 caaactttga ctyttggtac taaga 25 216 25 DNA Human 216 catcattgga caycatgaaa tatgt 25 217 25 DNA Human 217 atgaggaaaa ttyggtacat tcatt 25 218 25 DNA Human 218 aagtcattca casacacaag tgatt 25 219 25 DNA Human 219 tgactaaaaa gaytgagcgt ttgtg 25 220 25 DNA Human 220 acctaatatc taygaagcca attgt 25 221 25 DNA Human 221 tcagggatca tarcactgac aaaag 25 222 25 DNA Human 222 actaagatgc tgrgaagact gcagg 25 223 25 DNA Human 223 ttgcacggga gcrgttacaa cattt 25 224 25 DNA Human 224 gcatatcaga aaygtatgac cacaa 25 225 25 DNA Human 225 tgaaaccaag ttygtactct tggct 25 226 25 DNA Human 226 atttaatttg taytctttcg gaaat 25 227 25 DNA Human 227 aaatactgct taygtaactt aagag 25 228 25 DNA Human 228 aaagtctctt tcrtattagc taaac 25 229 25 DNA Human 229 ggcctaaaac carccacttt atatg 25 230 25 DNA Human 230 tggcttccaa gartcccctg gtcag 25 231 25 DNA Human 231 ttttcattga tasaagggtg agcca 25 232 25 DNA Human 232 aaagcagcaa gtytggccat ctaga 25 233 25 DNA Human 233 attctgcagg gaycatggcc agttt 25 234 25 DNA Human 234 agataaacct ttyaccacgt ctaga 25 235 25 DNA Human 235 caaacagctt taygaaaagt tttaa 25 236 25 DNA Human 236 gtcaggcaat taygagtact aggag 25 237 25 DNA Human 237 taatgctatt tcrtactata caact 25 238 25 DNA Human 238 gataaccaaa tcrtttttcg gattt 25 239 25 DNA Human 239 aaacttaact gcrttctcaa atagt 25 240 25 DNA Human 240 gatttgatcc ttrtaaattc catag 25 241 25 DNA Human 241 ttgcctttgg gargttcttt gagtt 25 242 25 DNA Human 242 tatcctcaaa ttyggtcact caggt 25 243 25 DNA Human 243 agcactttgt ttsaatgaaa ctata 25 244 25 DNA Human 244 ttcttgtgtc tcmacatttt gtatg 25 245 25 DNA Human 245 tattggttca gayactattc gaaat 25 246 25 DNA Human 246 caattgcaga gargttttca aatga 25 247 25 DNA Human 247 tagatgtgac tgkttcattt agcca 25 248 25 DNA Human 248 tgattccacc atyatctata gctcc 25 249 25 DNA Human 249 tgggatgtat acygtgagtc actaa 25 250 25 DNA Human 250 gagtctacca ttktattggg tacat 25 251 25 DNA Human 251 aacttcagaa tarttcaatt accct 25 252 25 DNA Human 252 aagtcttttc ctkttgaata ccatc 25 253 25 DNA Human 253 acattatggt atraactttg gctgc 25 254 25 DNA Human 254 atggcttaat cayaaggaac tacat 25 255 25 DNA Human 255 tccctacctg aawcaaccca gtgca 25 256 25 DNA Human 256 aactgctaca ttkggagctt tctga 25 257 25 DNA Human 257 ggtttgactg ccracgatgc taaga 25 258 25 DNA Human 258 tacaaagtag tgyagctgta catca 25 259 25 DNA Human 259 tctcaggaga agyggccctt ctgat 25 260 25 DNA Human 260 attgcaaact taygatattc acaaa 25 261 25 DNA Human 261 gtgcttgcct ccrctctatc gggcg 25 262 25 DNA Human 262 gatgcacgat acyagaaata agcat 25 263 25 DNA Human 263 atcgccttga taraaatatg atatg 25 264 25 DNA Human 264 ctactgcttc atygccctct agtac 25 265 25 DNA Human 265 ttgttgtgcg tgkcttggat agcaa 25 266 25 DNA Human 266 acctgtgcgt gcraaaccca tggca 25 267 25 DNA Human 267 tgcgggacct gcraaaatgt atccc 25 268 25 DNA Human 268 gtgtttttaa tcrtagctct ttact 25 269 25 DNA Human 269 acagtaacaa tcratcatta tgagc 25 270 25 DNA Human 270 tttttacttc ccrtcaaatc acaag 25 271 25 DNA Human 271 accattgaga ggktcccctt agcca 25 272 25 DNA Human 272 tcttatttta tcygattgaa ttgtg 25 273 25 DNA Human 273 atttcgtatt ttraatgccc cacaa 25 274 25 DNA Human 274 ccatgaaaga tgrctccaga aactt 25 275 25 DNA Human 275 tactgaccgt ccygacgctt tcagt 25 276 25 DNA Human 276 actttgtcac atsaaacaag atgag 25 277 25 DNA Human 277 ctttgaaaac tgygggatga gttag 25 278 25 DNA Human 278 tctgactcaa tcygcctgtc tttag 25 279 25 DNA Human 279 caggacacag ctyggggtca cggcg 25 280 25 DNA Human 280 ctgtctctac casgtaacac atgac 25 281 25 DNA Human 281 ctcggtcttg acrgtctgaa ttact 25 282 25 DNA Human 282 tccagacaaa ggratcagtg caagc 25 283 25 DNA Human 283 tctcctattt gtyccatggc agtta 25 284 25 DNA Human 284 gttactgacg ggmtttagcc attac 25 285 25 DNA Human 285 ttacttttca cartctctct aacat 25 286 25 DNA Human 286 ggttctgaga gcrccacaag gaaga 25 287 25 DNA Human 287 tatcttagcc tastagaatg gaatc 25 288 25 DNA Human 288 ttgagggtgt garttttctg tatcc 25 289 25 DNA Human 289 tactttgtcc ctstcataga acctg 25 290 25 DNA Human 290 gtgcattctt cawactgatt tggga 25 291 25 DNA Human 291 agcaggctaa agrtttcact gaagt 25 292 25 DNA Human 292 attatcattt gcrtaagcct ctcat 25 293 25 DNA Human 293 catacacttc caratcttct gtagc 25 294 25 DNA Human 294 aatgataaaa gaygacccat gcctt 25 295 25 DNA Human 295 caatctaatg ccrcaagaaa aaata 25 296 25 DNA Human 296 tgttattcca acyctgaaca catca 25 297 25 DNA Human 297 tgactgagag tartggacac agttt 25 298 25 DNA Human 298 gacacgctag acraagggcg tccat 25 299 25 DNA Human 299 tgggaatgta atmggcagtt taaga 25 300 25 DNA Human 300 gacttgaaaa aayccagact tttga 25 301 25 DNA Human 301 agaggaacaa aayggtaagt aatta 25 302 25 DNA Human 302 ccaaaactct tayaaattct atggt 25 303 25 DNA Human 303 acgaaaatca tamgactcta cggaa 25 304 25 DNA Human 304 caaatttcca ctrtcccgag aaggt 25 305 25 DNA Human 305 aaagtcattg ttstcaaatg ggatg 25 306 25 DNA Human 306 tatctttaag cartttagca agtag 25 307 25 DNA Human 307 gatgattaca gtrgtcgtag ttccc 25 308 25 DNA Human 308 agtaaatagc tcytttcttt gtaga 25 309 25 DNA Human 309 agtccttgaa gartgatcat aaaaa 25 310 25 DNA Human 310 gcggacctga gtkacctcat ggaac 25 311 25 DNA Human 311 atcagatgac cargaattga gagac 25 312 25 DNA Human 312 ctacagaggt acrtgcatag gtcca 25 313 25 DNA Human 313 tttttctata gayggccagc actgg 25 

What is claimed is:
 1. A method for identifying matched groups prior to performing a study, the method comprising: prior to performing a study, identifying members of a control group and members of a case group; for each of a number of selected genetic markers, genotyping a plurality of members in the control group and a plurality of members in the case group, wherein the genotyping identifies a set of alleles corresponding to the genetic markers for each member of the pluralities, and wherein the genetic markers are selected to identify differences in population structure between members; and determining if the groups are matched based on the genotypes of said case group and said control group.
 2. The method of claim 1, wherein determining if the groups are matched comprises: determining observed chi-squared score statistics of association with a phenotype based on counts of each genetic marker allele among members of the case and control groups; comparing a distribution of the observed chi-squared score statistics with an expected chi-squared score statistics distribution in a Q-Q plot; and determining if the differences between the observed and expected statistics distributions exceed an acceptable range, wherein if the differences between the observed and expected statistics distributions do not exceed an acceptable range the groups are determined to be matched.
 3. The method of claim 1, wherein determining if the groups are matched comprises: determining observed chi-squared score statistics of association with a phenotype based on counts of each genetic marker allele among members of the case and control groups; for each genetic marker, determining a p-value based on the observed chi-squared score statistics; comparing the distribution of smaller p-values for the observed chi-squared score statistics with an expected distribution of small p-values for chi-squared score statistics; and determining if the differences between the observed and expected distributions exceed an acceptable range, wherein if the differences between the observed and expected statistics do not exceed an acceptable range the groups are determined to be matched.
 4. The method of claim 1, wherein determining if the groups are matched comprises: determining observed chi-squared score statistics of association with a phenotype based on counts of each genetic marker allele among members of the case and control groups; computing a global p-value based on the sum of individual observed chi-squared score statistics; and determining if the global p-value for the given number of individuals in the study exceeds an acceptable threshold, wherein if the global p-value does exceed an acceptable threshold the groups are determined to be matched.
 5. The method of claim 1, further comprising performing an association study with said case and control groups, and identifying markers correlated with a phenotype.
 6. The method of claim 1, wherein the genetic markers are highly polymorphic across a set of globally diverse individuals.
 7. The method of claim 6, wherein said globally diverse populations comprise individuals with African, Asian, European, Native South American, and Native North American ancestry.
 8. The method of claim 1, wherein the genetic markers are substantially uniformly spaced across a genome.
 9. The method of claim 1, wherein the genetic markers are separated from one another by at least about 5 megabases in a genome.
 10. The method of claim 1, wherein the genetic markers are separated from one another by at least about 8 megabases in a genome.
 11. The method of claim 1, wherein the genetic markers are separated from one another by at least about 10 megabases in a genome.
 12. The method of claim 1, wherein the genetic markers are common single nucleotide polymorphisms.
 13. The method of claim 1, wherein the genetic markers are 312 single nucleotide polymorphisms described in Table
 1. 14. The method of claim 1, wherein the genetic markers comprise at least about 100 genetic markers that are not in linkage disequilibrium with one another.
 15. The method of claim 1, wherein the genotyping of a member includes: obtaining a DNA sample from the member; using multiplex polymerase chain reactions to amplify the DNA sample; applying the amplified DNA sample to a DNA array; and determining the alleles present in the DNA sample based onwhich probes in the DNA array hybridize with portions of the DNA sample.
 16. The method of claim 2, further comprising using the control group and the case group in an association study if the difference between the observed chi-squared test statistic distribution and expected chi-squared distribution does not exceed an acceptable range.
 17. The method of claim 2, further comprising adjusting the members of either or both of the control group and case group if the difference between the observed chi-squared test statistic distribution and expected chi-squared distribution does exceed an acceptable range.
 18. The method of claim 17, such that the adjusting results in the chi-squared test statistic distribution being similar to the expected chi-squared distribution.
 19. The method of claim 17, where the adjustment is based on results of a clustering analysis of the genotype data, and wherein the clustering analysis is used to estimate the proportional contribution of two or more ancestral human populations to the genetic background of each member of the pluralities.
 20. The method of claim 17, where adjusting includes assigning individuals in the case and control groups to strata based on their estimated ancestry, and then removing a minimum number of individuals such that the proportion of cases in each of the strata is nearly the same.
 21. The method of claim 17, wherein the adjusting includes: removing members of either or both of the case and control groups until the average population structure for the case and control groups is equivalent.
 22. The method of claim 17, wherein adjusting includes (i) performing a regression analysis of the quantitative phenotype of interest against the population structure estimates, and then (ii) defining adjusted case and control groups based on adjusted measurements where the expected contribution of an individual's ancestry, determined from the regression analysis, is subtracted from that individual's phenotype measurement.
 23. The method of claim 1, wherein the selected genetic markers are (i) polymorphic across globally diverse individuals, separated along a genome by at least about 5 megabases, and (ii) separated from repeat sequences by at least about 150 base pairs.
 24. A method for performing an association study comprising: determining if study populations are matched; adjusting the study populations that are not matched such that they become matched; and then comparing the study populations to identify genetic loci that correlate with a phenotypic trait of interest.
 25. The method of claim 24, wherein said determining step comprises comparing the allele frequencies of genetic markers between the study populations.
 26. The method of claim 25, wherein said genetic markers are SNPs selected from the group consisting of: common SNPs; SNPs that are uniformly distributed across a genome; biallelic SNPs; and SNPs that are not in linkage disequilibrium with one another.
 27. The method of claim 24, wherein adjusting the study populations comprises: (i) performing a stratification analysis on the study populations; and (ii) balancing the relative contributions of strata identified by the stratification analysis across the study groups.
 28. The method of claim 27, wherein balancing the relative contributions of the strata comprises eliminating members of particular strata disproportionately represented in one study population.
 29. The method of claim 27, wherein balancing the relative contributions of the strata comprises gradually removing outlier individuals from one or more study groups and recomputing mean allele frequencies for the one or more study groups until the mean allele frequencies reach an acceptable level similarity.
 30. A method for detecting and correcting population structure of study groups so that they are matched, said method comprising; a) identifying members of a control group and members of a case group; b) for each of a number of selected genetic markers, genotyping a plurality of members in the control group and a plurality of members in the case group, wherein the genotyping identifies a set of alleles corresponding to the genetic markers for each member of the pluralities, and wherein the genetic markers are selected to identify differences in population structure between members; and c) determining if the groups are matched based on the genotypes of said case group and said control group.
 31. The method of claim 30, wherein the genetic markers are substantially uniformly spaced across a genome.
 32. The method of claim 30, wherein the genetic markers are separated from one another by at least about 5 megabases in a genome.
 33. The method of claim 30, wherein the genetic markers are separated from one another by at least about 8 megabases in a genome.
 34. The method of claim 30, wherein the genetic markers are separated from one another by at least about 10 megabases in a genome.
 35. The method of claim 30, wherein the genetic markers are common single nucleotide polymorphisms.
 36. The method of claim 30, wherein the genetic markers include one or more of the single nucleotide polymorphisms described in Table
 1. 37. The method of claim 30, wherein the selected genetic markers include at least 100 markers.
 38. A method for performing an association study comprising: determining if study populations are matched by comparing the allele frequencies of genetic markers between the study populations; and comparing the study populations to identify genetic loci that correlate with a phenotypic trait of interest.
 39. The method of claim 38, wherein if the study populations are not matched, adjusting the study populations such that they become matched.
 40. The method of claim 38, wherein said genetic markers are SNPs selected from the group consisting of common SNPs, SNPs that are uniformly distributed across a genome, biallelic SNPs, and SNPs that are not in linkage disequilibrium with one another.
 41. The method of claim 38, wherein the genetic markers comprise at least about 100 genetic markers that are not in linkage disequilibrium with one another.
 42. A method for identifying matched groups prior to performing an association study, the method comprising: providing an observed frequency distribution for a case group and a control group, wherein the observed frequency distribution is based on results of genotyping a plurality of members in a case group and a plurality of members in a control group to identify a set of alleles corresponding to the genetic markers for each member of the pluralities, and wherein the observed frequency distribution is based on the differences between the frequency of alleles at each marker for the case and control groups; comparing the observed frequency distribution to an expected frequency distribution, wherein the expected frequency distribution represents a frequency distribution for two populations having statistically equivalent population structure compositions; and adjusting the membership of either or both of the case group and control group to reduce differences between the observed frequency distribution and the expected frequency distribution.
 43. The method of claim 42, wherein the adjusting is based on results of a clustering analysis performed on the genotype data, and wherein the results of the clustering algorithm includes an estimation of proportional contributions of two or more ancestral human populations to each member of the pluralities.
 44. The method of claim 42, wherein the adjusting includes: assigning each member of the pluralities to strata for the case and control groups, wherein the strata for the case and control groups represent different proportions of two or more human ancestral backgrounds, and removing members from one or both of the pluralities such that the proportion of members in each of the strata is nearly the same for the case and control groups.
 45. The method of claim 42, wherein the adjusting includes: removing members of one or both of the case and control groups to produce a substantially equivalent average population structure for the case and control groups.
 46. The method of claim 42, wherein adjusting includes using a regression analysis to define case and control groups.
 47. A method of selecting markers to identify matched groups prior to performing an association study, the method comprising: identifying a pool of biallelic markers; from the pool of biallelic markers, selecting at least about 50 markers separated from one another along a genome by at least about 5 megabases, wherein the selected markers are polymorphic, with each allele represented at a level of at least about 40% across globally diverse populations, and wherein the selected markers are separated from repeat sequences by at least about 150 base pairs.
 48. The method of claim 47, wherein the selected markers are SNPS.
 49. The method of claim 47, wherein the selected markers are separated from a haplotype block boundary by at least two SNPs.
 50. The method of claim 47, wherein the selected markers are found on genome sequences that were found to provide strict calls on a SNP discovery probe array.
 51. The method of claim 47, wherein the selected markers are microsatellites.
 52. A computer program product comprising a machine readable medium on which is provided program instructions for identifying matched groups, the program instructions comprising: code for providing an observed frequency distribution for a case group and a control group, wherein the observed frequency distribution is based on results of genotyping a plurality of members in a case group and a plurality of members in a control group to identify a set of alleles corresponding to the genetic markers for each member of the pluralities, and wherein the observed frequency distribution is based on the differences between the frequency of alleles at each marker for the case and control groups; code for comparing the observed frequency distribution to an expected frequency distribution, wherein the expected frequency distribution represents a frequency distribution for two populations having statistically equivalent population structure compositions; and code for adjusting the membership of either or both of the case group and control group to reduce differences between the observed frequency distribution and the expected frequency distribution.
 53. A computer program product comprising a machine readable medium on which is provided program instructions for performing an association study, the program instructions comprising: code for determining if study populations are matched; code adjusting the study populations that are not matched such that they become matched; and code for comparing the study populations to identify genetic loci that correlate with a phenotypic trait of interest.
 54. The computer program product of claim 53, wherein said code for determining comprises code for comparing the allele frequencies of genetic markers between the study populations.
 55. The computer program product of claim 53, wherein the code for adjusting the study populations comprises: (i) code for performing a stratification analysis on the study populations; and (ii) code for balancing the relative contributions of strata identified by the stratification analysis across the study groups.
 56. A computer program product comprising a machine readable medium on which is provided program instructions for performing an matching population structure of study populations, the program instructions comprising: code for determining if study populations are matched; code adjusting the study populations that are not matched such that they become matched by (i) performing a stratification analysis on the study populations; and (ii) balancing the relative contributions of strata identified by the stratification analysis across the study groups.
 57. The computer program product of claim 56, wherein balancing the relative contributions of the strata comprises eliminating members of particular strata disproportionately represented in one study population.
 58. The computer program product of claim 56, wherein balancing the relative contributions of the strata comprises gradually removing outlier individuals from one or more study groups and recomputing mean allele frequencies for the one or more study groups until the mean allele frequencies reach an acceptable level similarity. 